81 FR 9950 - Takes of Marine Mammals Incidental to Specified Activities; U.S. Navy Training Activities in the Gulf of Alaska Temporary Maritime Activities Area

DEPARTMENT OF COMMERCE
National Oceanic and Atmospheric Administration

Federal Register Volume 81, Issue 38 (February 26, 2016)

Page Range		9950-10023
FR Document		2016-03622

NMFS has received a request from the U.S. Navy (Navy) for authorization to take marine mammals incidental to the training activities conducted in the Gulf of Alaska (GOA) Temporary Maritime Activities Area (TMAA) Study Area (hereafter referred to the Study Area) from May 2016 through May 2021. Pursuant to the Marine Mammal Protection Act (MMPA), NMFS is requesting comments on its proposal to issue regulations and subsequent Letter of Authorization (LOA) to the Navy to incidentally harass marine mammals.

Federal Register, Volume 81 Issue 38 (Friday, February 26, 2016)

[Federal Register Volume 81, Number 38 (Friday, February 26, 2016)]
[Proposed Rules]
[Pages 9950-10023]
From the Federal Register Online [www.thefederalregister.org]
[FR Doc No: 2016-03622]

[[Page 9949]]

Vol. 81

Friday,

No. 38

February 26, 2016

Part II

Department of Commerce

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National Oceanic and Atmospheric Administration

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50 CFR Part 218

Takes of Marine Mammals Incidental to Specified Activities; U.S. Navy
Training Activities in the Gulf of Alaska Temporary Maritime Activities
Area; Proposed Rule

Federal Register / Vol. 81 , No. 38 / Friday, February 26, 2016 /
Proposed Rules

[[Page 9950]]

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DEPARTMENT OF COMMERCE

National Oceanic and Atmospheric Administration

50 CFR Part 218

[Docket No. 141125997-6058-01]
RIN 0648-BE67

Takes of Marine Mammals Incidental to Specified Activities; U.S.
Navy Training Activities in the Gulf of Alaska Temporary Maritime
Activities Area

AGENCY: National Marine Fisheries Service (NMFS), National Oceanic and
Atmospheric Administration (NOAA), Commerce.

ACTION: Proposed rule; request for comments and information.

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SUMMARY: NMFS has received a request from the U.S. Navy (Navy) for
authorization to take marine mammals incidental to the training
activities conducted in the Gulf of Alaska (GOA) Temporary Maritime
Activities Area (TMAA) Study Area (hereafter referred to the Study
Area) from May 2016 through May 2021. Pursuant to the Marine Mammal
Protection Act (MMPA), NMFS is requesting comments on its proposal to
issue regulations and subsequent Letter of Authorization (LOA) to the
Navy to incidentally harass marine mammals.

DATES: Comments and information must be received no later than March
28, 2016.

ADDRESSES: You may submit comments, identified by NOAA-NMFS-2016-0008,
by any of the following methods:
Electronic submissions: submit all electronic public
comments via the Federal eRulemaking Portal, Go to www.regulations.gov/#!docketDetail;D=NOAA-NMFS-2016-0008, click the ``Comment Now!'' icon,
complete the required fields, and enter or attach your comments.
Mail: Submit comments to Jolie Harrison, Chief, Permits
and Conservation Division, Office of Protected Resources, National
Marine Fisheries Service, 1315 East-West Highway, Silver Spring, MD
20910-3225.
Fax: (301) 713-0376; Attn: Jolie Harrison.
Instructions: Comments sent by any other method, to any other
address or individual, or received after the end of the comment period,
may not be considered by NMFS. All comments received are a part of the
public record and will generally be posted for public viewing on
www.regulations.gov without change. All personal identifying
information (e.g., name, address, etc.), confidential business
information, or otherwise sensitive information submitted voluntarily
by the sender will be publicly accessible. NMFS will accept anonymous
comments (enter ``N/A'' in the required fields if you wish to remain
anonymous). Attachments to electronic comments will be accepted in
Microsoft Word, Excel, or Adobe PDF file formats only.

FOR FURTHER INFORMATION CONTACT: John Fiorentino, Office of Protected
Resources, NMFS, (301) 427-8477.

SUPPLEMENTARY INFORMATION:

Availability

A copy of the Navy's LOA application, which contains a list of the
references used in this proposed rule, may be obtained by visiting the
internet at: http://www.nmfs.noaa.gov/pr/permits/incidental/military.htm. The Navy is preparing a Supplemental Environmental Impact
Statement (SEIS)/Overseas EIS (OEIS) for the GOA TMAA Study Area to
evaluate all components of the proposed training activities. The Navy
previously analyzed training activities in the Study Area in the 2011
GOA Navy Training Activities FEIS (GOA FEIS/OEIS) (U.S. Department of
the Navy, 2011a). The GOA Draft Supplemental EIS (DSEIS)/OEIS was
released to the public on August 23, 2014, for review until October 22,
2014. The Navy is the lead agency for the GOA SEIS/OEIS, and NMFS is a
cooperating agency pursuant to 40 CFR 1501.6 and 1508.5. The GOA DSEIS/
OEIS, which also contains a list of the references used in this
proposed rule, may be viewed at: http://www.goaeis.com. Documents cited
in this notice may also be viewed, by appointment, during regular
business hours, at the aforementioned address.

Background

Sections 101(a)(5)(A) and (D) of the MMPA (16 U.S.C. 1361 et seq.)
direct the Secretary of Commerce to allow, upon request, the
incidental, but not intentional, taking of small numbers of marine
mammals by U.S. citizens who engage in a specified activity (other than
commercial fishing) within a specified geographical region if certain
findings are made and either regulations are issued or, if the taking
is limited to harassment, a notice of a proposed authorization is
provided to the public for review.
Authorization for incidental takings shall be granted if NMFS finds
that the taking will have a negligible impact on the species or
stock(s), will not have an unmitigable adverse impact on the
availability of the species or stock(s) for subsistence uses (where
relevant), and if the permissible methods of taking and requirements
pertaining to the mitigation, monitoring, and reporting of such takings
are set forth. NMFS has defined ``negligible impact'' in 50 CFR 216.103
as ``an impact resulting from the specified activity that cannot be
reasonably expected to, and is not reasonably likely to, adversely
affect the species or stock through effects on annual rates of
recruitment or survival.''
The National Defense Authorization Act of 2004 (NDAA) (Pub. L. 108-
136) removed the ``small numbers'' and ``specified geographical
region'' limitations indicated above and amended the definition of
``harassment'' as applies to a ``military readiness activity'' to read
as follows (section 3(18)(B) of the MMPA, 16 U.S.C. 1362(18)(B)): ``(i)
any act that injures or has the significant potential to injure a
marine mammal or marine mammal stock in the wild'' [Level A
Harassment]; or ``(ii) any act that disturbs or is likely to disturb a
marine mammal or marine mammal stock in the wild by causing disruption
of natural behavioral patterns, including, but not limited to,
migration, surfacing, nursing, breeding, feeding, or sheltering, to a
point where such behavioral patterns are abandoned or significantly
altered'' [Level B Harassment].

Summary of Request

On July 28, 2014, NMFS received an application from the Navy
requesting a LOA for the take of 19 species of marine mammals
incidental to Navy training activities to be conducted in the Study
Area over 5 years. On October 14, 2014, the Navy submitted a revised
LOA application to reflect minor changes in the number and types of
training activities. To address minor inconsistencies with the DSEIS,
the Navy submitted a final revision to the LOA application (hereafter
referred to as the LOA application) on January 21, 2015.
The Navy is requesting a 5-year LOA for training activities to be
conducted from 2016 through 2021. The Study Area is a polygon roughly
the shape of a 300 nm by 150 nm rectangle oriented northwest to
southeast in the long direction, located south of Prince William Sound
and east of Kodiak Island, Alaska (see Figure 1-1 of the LOA
application for a map of the Study Area). The activities conducted
within the Study Area are classified as military readiness activities.
The Navy states that these activities may expose some of the marine
mammals present within the Study Area to sound from underwater

[[Page 9951]]

acoustic sources and explosives. The Navy requests authorization to
take 19 marine mammal species by Level B (behavioral) harassment; one
of those marine mammal species (Dall's porpoise) may be taken by Level
A (injury) harassment. The Navy is not requesting mortality takes for
any species.
The LOA application and the GOA DSEIS/OEIS contain acoustic
thresholds that, in some instances, represent changes from what NMFS
has used to evaluate the Navy's activities for previous authorizations.
The revised thresholds, which the Navy developed in coordination with
NMFS, are based on the evaluation and inclusion of new information from
recent scientific studies; a detailed explanation of how they were
derived is provided in the GOA DSEIS/OEIS Criteria and Thresholds for
U.S. Navy Acoustic and Explosive Effects Analysis Technical Report
(available at http://www.goaeis.com). The revised thresholds are
adopted for this proposed rulemaking.
NOAA is currently in the process of developing Acoustic Guidance on
thresholds for onset of auditory impacts from exposure to sound, which
will be used to support assessments of the effects of anthropogenic
sound on marine mammals. To develop this Guidance, NOAA is compiling,
interpreting, and synthesizing the best information currently available
on the effects of anthropogenic sound on marine mammals, and is
committed to finalizing the Guidance through a systematic, transparent
process that involves internal review, external peer review, and public
comment.
In December 2013, NOAA released for public comment a ``Draft
Guidance for Assessing the Effects of Anthropogenic Sound on Marine
Mammals: Acoustic Threshold Levels for Onset of Permanent and Temporary
Threshold Shifts'' (78 FR 78822) (the term ``threshold shift'' refers
to noise-induced hearing loss). The Draft Guidance was generally
consistent with the Navy's Permanent Threshold Shifts/Temporary
Threshold Shifts (PTS/TTS) criteria used in the GOA DSEIS/OEIS and
detailed within Finneran and Jenkins (2012). Prior to the finalization
of this guidance by NOAA, the Navy suggested revisions to the criteria
(e.g., auditory weighting functions and PTS/TTS thresholds) based on a
number of studies available since the Navy's Phase 2 modeling (the
acoustic effects modeling currently employed by the Navy for training
and testing activities), including Finneran et al. (2005), Finneran et
al. (2010), Finneran and Schlundt (2013), Kastelein et al. (2012a),
Kastelein et al. (2012b), Kastelein et al. (2014a), Kastelein et al.
(2014b), Popov et al. (2013), and Popov et al. (2011). In January 2015,
the Navy submitted a draft proposal (Finneran 2015) to NOAA staff for
their consideration.
Finneran (2015) proposed new weighting functions and thresholds for
predicting PTS/TTS in marine mammals. The methodologies presented
within this paper build upon the methodologies used to develop the
criteria applied within the Navy's GOA DSEIS/OEIS (Finneran and
Jenkins, 2012) and incorporate relevant auditory research made
available since 2012. While Finneran and Jenkins (2012) presented a
conservative approach to development of auditory weighting functions
where data was limited, Finneran (2015) synthesizes a wide range of
auditory data, including newly available studies, to predict refined
auditory weighting functions and corresponding TTS thresholds across
the complete hearing ranges of functional hearing groups.
During the development process of NOAA's Draft Guidance, NOAA
incorporated Finneran (2015) into its Draft Guidance. As a result, the
Navy's proposal (Finneran, 2015) was submitted for peer review by
external subject matter experts, in accordance with the process
previously conducted for NOAA's Draft Guidance. Peer review comments
were received by NOAA in April 2015. NOAA subsequently developed a Peer
Review Report, which was published on its Web site on July 31, 2015.
The published report documents the Navy's proposal (Finneran, 2015)
that underwent peer review, the peer-review comments, and NOAA's
responses to those comments. NOAA then incorporated this information
into revised Draft Guidance which was published in the Federal Register
for public review and comment (80 FR 45642) on July 31, 2015. The
auditory weighting functions and PTS/TTS thresholds provided in that
revised Draft Guidance will not be adopted by NOAA or applied to
applicants until Final Guidance is issued. At the time of this proposed
rulemaking, Final Guidance has not been issued. Therefore, the Navy has
not adopted these proposed criteria in its GOA DSEIS/OEIS. However, the
underlying science contained within Finneran (2015) has been addressed
qualitatively within the applicable sections of the GOA DSEIS/OEIS and
this rulemaking.
If the proposed criteria in Finneran (2015) were adopted by NOAA,
incorporated into its Final Guidance, and applied to the Navy in the
future, predicted numbers of PTS/TTS would change for most functional
hearing groups. However, because Finneran (2015) relies on much of the
same data as the auditory criteria presented in the Navy's GOA DSEIS/
OEIS, these changes would not be substantial, and in most cases would
result in a reduction in the predicted impacts. Predicted PTS/TTS would
be reduced over much to all of their hearing range for low-frequency
cetaceans and phocids. Predicted PTS/TTS for mid-frequency and high-
frequency cetaceans would be reduced for sources with frequencies below
about 3.5 kHz and remain relatively unchanged for sounds above this
frequency. Predicted auditory effects on otariids would increase for
frequencies between about 1 kHz and 20 kHz and decrease for frequencies
above and below these points, although otariids remain the marine
mammals with the least sensitivity to potential PTS/TTS. Overall,
predicted auditory effects within this rulemaking would not change
significantly.
In summary, NOAA's continuing evaluation of all available science
for the Acoustic Guidance could result in changes to the acoustic
criteria used to model the Navy's activities for this rulemaking, and,
consequently, the enumerations of ``take'' estimates. However, at this
time, the results of prior Navy modeling described in this notice
represent the best available estimate of the number and type of take
that may result from the Navy's use of acoustic sources in the GOA
Study Area. Further, consideration of the revised Draft Guidance and
information contained in Finneran (2015) does not alter our assessment
of the likely responses of marine mammals to acoustic sources employed
by Navy in the GOA Study Area, or the likely fitness consequences of
those responses. Finally, while acoustic criteria may also inform
mitigation and monitoring decisions, this rulemaking requires a robust
adaptive management program that regularly addresses new information
and allows for modification of mitigation and/or monitoring measures as
appropriate.

Background of Request

The Navy's mission is to organize, train, equip, and maintain
combat-ready naval forces capable of winning wars, deterring
aggression, and maintaining freedom of the seas. This mission is
mandated by federal law (10 U.S.C. 5062), which ensures the readiness
of

[[Page 9952]]

the naval forces of the United States.\1\ The Navy executes this
responsibility by establishing and executing training programs,
including at-sea training and exercises, and ensuring naval forces have
access to the ranges, operating areas (OPAREAs), and airspace needed to
develop and maintain skills for conducting naval activities.
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\1\ Title 10, Section 5062 of the U.S.C.
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The Navy proposes to continue conducting training activities within
the Study Area, which have been ongoing since the 1990s. The tempo and
types of training activities have fluctuated because of the
introduction of new technologies, the evolving nature of international
events, advances in war fighting doctrine and procedures, and force
structure (organization of ships, submarines, aircraft, weapons, and
personnel) changes. Such developments influence the frequency,
duration, intensity, and location of required training activities.
The Navy's LOA request covers training activities that would occur
for a 5-year period following the expiration of the current MMPA
authorization for the GOA TMAA, which expires in 2016.

Description of the Specified Activity

The Navy is requesting authorization to take marine mammals
incidental to conducting training activities. The Navy has determined
that sonar use and underwater detonations are the stressors most likely
to result in impacts on marine mammals that could rise to the level of
harassment. Detailed descriptions of these activities are provided in
the DSEIS/OEIS and in the LOA application (http://www.nmfs.noaa.gov/pr/permits/incidental/military.htm) and are summarized here.

Overview of Training Activities

The Navy routinely trains in the Study Area in preparation for
national defense missions. Training activities and exercises covered in
the Navy's LOA request are briefly described below, and in more detail
within chapter 2 of the GOA DSEIS/OEIS. Each military training activity
described meets a requirement that can be traced ultimately to
requirements set forth by the National Command Authority.\2\
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\2\ ``National Command Authority'' is a term used by the United
States military and government to refer to the ultimate lawful
source of military orders. The term refers collectively to the
President of the United States (as commander-in-chief) and the
United States Secretary of Defense.
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The Navy categorizes training activities into eight functional
warfare areas called primary mission areas: anti-air warfare;
amphibious warfare; strike warfare; anti-surface warfare (ASUW); anti-
submarine warfare (ASW); electronic warfare; mine warfare (MIW); and
naval special warfare (NSW). Most training activities are categorized
under one of these primary mission areas; those activities that do not
fall within one of these areas are in a separate ``other'' category.
Each warfare community (surface, subsurface, aviation, and special
warfare) may train within some or all of these primary mission areas.
However, not all primary mission areas are conducted within the Study
Area.
The Navy described and analyzed the effects of its training
activities within the GOA DSEIS/OEIS. In its assessment, the Navy
concluded that of the activities conducted within the Study Area, sonar
use and underwater detonations were the stressors resulting in impacts
on marine mammals that could rise to the level of harassment as defined
under the MMPA. Therefore, the LOA application provides the Navy's
assessment of potential effects from these stressors. The specific
acoustic sources used in the LOA application are contained in the GOA
DSEIS/OEIS and are presented in the following sections based on the
primary mission areas.

Anti-Surface Warfare (ASUW)

The mission of ASUW is to defend against enemy ships or boats. In
the conduct of ASUW, aircraft use cannons, air-launched cruise missiles
or other precision-guided munitions; ships employ torpedoes, naval
guns, and surface-to-surface (S-S) missiles; and submarines attack
surface ships using torpedoes or submarine-launched, anti-ship cruise
missiles.
Anti-surface warfare training in the Study Area includes S-S
gunnery and missile exercises (GUNEX and MISSILEX) and air-to-surface
(A-S) bombing exercises (BOMBEX), GUNEX, and MISSILEX. Also included in
this mission area is a sinking exercise that may include S-S and A-S
components.

Anti-Submarine Warfare (ASW)

The mission of ASW is to locate, neutralize, and defeat hostile
submarine threats to surface forces. ASW is based on the principle of a
layered defense of surveillance and attack aircraft, ships, and
submarines all searching for hostile submarines. These forces operate
together or independently to gain early warning and detection, and to
localize, track, target, and attack hostile submarine threats.
Anti-submarine warfare training addresses basic skills such as
detection and classification of submarines, distinguishing between
sounds made by enemy submarines and those of friendly submarines,
ships, and marine life. ASW training evaluates the ability of fleet
assets to use systems, for example, active and passive sonar and
torpedo systems to counter hostile submarine threats. More advanced,
integrated ASW training exercises are conducted in coordinated, at-sea
training events involving submarines, ships, and aircraft. This
training integrates the full spectrum of ASW from detecting and
tracking a submarine to attacking a target using simulated weapons.

Description of Sonar, Ordnance, Targets, and Other Systems

The Navy uses a variety of sensors, platforms, weapons, and other
devices to meet its mission. Training with these systems and devices
may introduce acoustic (sound) energy into the environment. The Navy's
current LOA application describes underwater sound as one of two types:
impulsive and non-impulsive. Sonar and similar sound producing systems
are categorized as non-impulsive sound sources. Underwater detonations
of explosives and other percussive events are impulsive sounds.

Sonar and Other Active Acoustic Sources

Modern sonar technology includes a variety of sonar sensor and
processing systems. In concept, the simplest active sonar emits sound
waves, or ``pings,'' sent out in multiple directions, and the sound
waves then reflect off of the target object in multiple directions. The
sonar source calculates the time it takes for the reflected sound waves
to return; this calculation determines the distance to the target
object. More sophisticated active sonar systems emit a ping and then
rapidly scan or listen to the sound waves in a specific area. This
provides both distance to the target and directional information. Even
more advanced sonar systems use multiple receivers to listen to echoes
from several directions simultaneously and provide efficient detection
of both direction and distance. Active sonar is rarely used
continuously throughout the listed activities. In general, when sonar
is in use, the sonar `pings' occur at intervals, referred to as a duty
cycle, and the signals themselves are very short in duration. For
example, sonar that emits a 1-second ping every 10 seconds has a 10
percent duty cycle. The Navy's largest hull-mounted mid-frequency sonar
source typically emits a 1-second ping every 50 seconds representing a
2 percent duty cycle. The Navy utilizes sonar systems and other
acoustic sensors in support of a variety of

[[Page 9953]]

mission requirements. Primary uses include the detection of and defense
against submarines (ASW) and mines (MIW); safe navigation and effective
communications; use of unmanned undersea vehicles; and oceanographic
surveys. Sources of sonar and other active acoustic sources include
surface ship sonar, sonobuoys, torpedoes, and unmanned underwater
vehicles.

Ordnance and Munitions

Most ordnance and munitions used during training events fall into
three basic categories: Projectiles (such as gun rounds), missiles
(including rockets), and bombs. Ordnance can be further defined by
their net explosive weight (NEW), which considers the type and quantity
of the explosive substance without the packaging, casings, bullets,
etc. NEW is the trinitrotoluene (TNT) equivalent of energetic material,
which is the standard measure of strength of bombs and other
explosives. For example, a 5-inch shell fired from a Navy gun is
analyzed at approximately 9.5 pounds (lb.) (4.3 kilograms [kg]) of NEW.
The Navy also uses non-explosive ordnance in place of explosive
ordnance in many training and testing events. Non-explosive ordnance
look and perform similarly to explosive ordnance, but lack the main
explosive charge.

Defense Countermeasures

Naval forces depend on effective defensive countermeasures to
protect themselves against missile and torpedo attack. Defensive
countermeasures are devices designed to confuse, distract, and confound
precision-guided munitions. Defensive countermeasures analyzed in this
LOA application include acoustic countermeasures, which are used by
surface ships and submarines to defend against torpedo attack. Acoustic
countermeasures are either released from ships and submarines, or towed
at a distance behind the ship.

Classification of Non-Impulsive and Impulsive Sources Analyzed

In order to better organize and facilitate the analysis of
approximately 300 individual sources of underwater acoustic sound or
explosive energy, a series of source classifications, or source bins,
were developed by the Navy. The use of source classification bins
provides the following benefits:
Provides the ability for new sensors or munitions to be
covered under existing regulatory authorizations, as long as those
sources fall within the parameters of a ``bin'';
Simplifies the source utilization data collection and
reporting requirements anticipated under the MMPA;
Ensures a conservative approach to all impact analysis, as
all sources in a single bin are modeled as the loudest source (e.g.,
lowest frequency, highest source level [the term ``source level''
refers to the loudness of a sound at its source], longest duty cycle,
or largest net explosive weight [NEW]) within that bin, which:
[cir] Allows analysis to be conducted more efficiently, without
compromising the results; and
[cir] Provides a framework to support the reallocation of source
usage (hours/explosives) between different source bins, as long as the
total number and severity of marine mammal takes remain within the
overall analyzed and authorized limits. This flexibility is required to
support evolving Navy training requirements, which are linked to real
world events.
There are two primary types of acoustic sources: Impulsive and non-
impulsive. A description of each source classification is provided in
Tables 1 and 2. Impulsive source class bins are based on the NEW of the
munitions or explosive devices or the source level for air and water
guns. Non-impulsive acoustic sources are grouped into source class bins
based on the frequency,\3\ source level,\4\ and, when warranted, the
application in which the source would be used. The following factors
further describe the considerations associated with the development of
non-impulsive source bins:
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\3\ Bins are based on the typical center frequency of the
source. Although harmonics may be present, those harmonics would be
several decibels (dB) lower than the primary frequency.
\4\ Source decibel levels are expressed in terms of sound
pressure level (SPL) and are values given in dB referenced to 1
micropascal at 1 meter.

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Frequency of the non-impulsive source.

[cir] Low-frequency sources operate below 1 kilohertz (kHz)
[cir] Mid-frequency sources operate at and above 1 kHz, up to and
including 10 kHz
[cir] High-frequency sources operate above 10 kHz, up to and including
100 kHz
[cir] Very high-frequency sources operate above 100 kHz but below 200
kHz

Source level of the non-impulsive source.

[cir] Greater than 160 decibels (dB), but less than 180 dB
[cir] Equal to 180 dB and up to 200 dB
[cir] Greater than 200 dB

Application in which the source would be used.
[cir] How a sensor is employed supports how the sensor's acoustic
emissions are analyzed.
[cir] Factors considered include pulse length (time source is on);
beam pattern (whether sound is emitted as a narrow, focused beam or, as
with most explosives, in all directions); and duty cycle (how often or
how many times a transmission occurs in a given time period during an
event).
As described in the GOA DSEIS/OEIS, non-impulsive acoustic sources
that have low source levels (not loud), narrow beam widths, downward
directed transmission, short pulse lengths, frequencies beyond known
hearing ranges of marine mammals, or some combination of these
characteristics, are not anticipated to result in takes of protected
species and therefore were not modeled. These sources generally meet
the following criteria and are qualitatively analyzed in the GOA DSEIS/
OEIS:

Acoustic sources with frequencies greater than 200 kHz (based
on known marine mammal hearing ranges)
Sources with source levels less than 160 dB

Table 1--Impulsive (Explosive) Training Source Classes Analyzed
------------------------------------------------------------------------
Representative Net explosive weight
Source class munitions (lbs)
------------------------------------------------------------------------
E5....................... 5-inch projectiles. >5-10
E6....................... AGM-114 Hellfire >10-20
missile.
E7....................... AGM-88 High-speed >20-60
Anti-Radiation
Missile.
E8....................... 250 lb. bomb....... >60-100
E9....................... 500 lb. bomb....... >100-250

[[Page 9954]]

E10...................... 1,000 lb. bomb/Air- >250-500
to-surface missile.
E11...................... MK-48 torpedo...... >500-650
E12...................... 2,000 lb. bomb..... >650-1,000
------------------------------------------------------------------------

Table 2--Non-Impulsive Training Source Classes Analyzed.
------------------------------------------------------------------------
Description of
Source class category Source class representative sources
------------------------------------------------------------------------
Mid-Frequency (MF): Tactical and MF1 Hull-mounted surface
non-tactical sources that ship sonar (e.g., AN/
produce mid-frequency (1-10 SQS-53C and AN/SQS-
kHz) signals. 60).
MF3 Hull-mounted submarine
sonar (e.g., AN/BQQ-
10).
MF4 Helicopter-deployed
dipping sonar (e.g.,
AN/AQS-22 and AN/AQS-
13).
MF5 Active acoustic
sonobuoys (e.g.,
DICASS).
MF6 Active underwater sound
signal devices (e.g.,
MK-84).
MF11 Hull-mounted surface
ship sonar with an
active duty cycle
greater than 80%.
High-Frequency (HF): Tactical HF1 Hull-mounted submarine
and non-tactical sources that HF6 sonar (e.g., AN/BQQ-
produce high[dash]frequency 10).
(greater than 10 kHz but less Active sources (equal
than 100 kHz) signals. to 180 dB and up to
200 dB).
Anti-Submarine Warfare (ASW): ASW2
Tactical sources such as active
sonobuoys and acoustic
countermeasures systems used
during the conduct of ASW
training activities.
ASW3 Mid-frequency
Multistatic Active
Coherent sonobuoy
(e.g., AN/SSQ-125).
Mid-frequency towed
active acoustic
countermeasure systems
(e.g., AN/SLQ-25).
ASW4 Mid-frequency
expendable active
acoustic device
countermeasures (e.g.,
MK-3).
Torpedoes (TORP): Source classes TORP2 Heavyweight torpedo
associated with the active (e.g., MK-48, electric
acoustic signals produced by vehicles).
torpedoes.
------------------------------------------------------------------------
Notes: dB = decibels, DICASS = Directional Command Activated Sonobuoy
System, kHz = kilohertz

Training

The training activities that the Navy proposes to conduct in the
Study Area are described in Table 3. The table is organized according
to primary mission areas and includes the activity name, associated
stressor(s), description of the activity, the primary platform used
(e.g., ship or aircraft type), duration of activity, type of non-
impulsive or impulsive sources used in the activity, and the number of
activities per year. More detailed activity descriptions can be found
in chapter 2 of the GOA DSEIS/OEIS. The Navy's Proposed Activities are
anticipated to meet training needs in the years 2016-2021.

Table 3--Training Activities Within the Study Area
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Weapons/rounds/sound
Category Training activity Description source
----------------------------------------------------------------------------------------------------------------
Anti-Surface Warfare (ASUW)
Impulsive...................... Gunnery Exercise, Ship crews engage surface Small-, Medium-, and
Surface-to-Surface targets with ship's small- Large-caliber high
(Ship) (GUNEX-S-S , medium-, and large- explosive rounds.
[Ship]). caliber guns. Some of the
small- and medium-caliber
gunnery exercises analyzed
include those conducted by
the U.S. Coast Guard.
Impulsive...................... Sinking Exercise...... Fixed-wing aircrews, High explosive bombs,
surface ships and missiles, Large-
submarine firing precision- caliber rounds and
guided and non-precision torpedoes.
weapons against a surface
target.
Impulsive...................... Bombing Exercise (Air- Fixed-wing aircrews deliver High explosive bombs.
to-Surface) (BOMBEX bombs against surface
[A-S]). targets.
Anti-Submarine Warfare (ASW)
Non-impulsive.................. Tracking Exercise-- Submarine searches for, Mid- and high-
Submarine (TRACKEX-- detects, and tracks frequency submarine
Sub). submarine(s) and surface sonar.
ship(s).

[[Page 9955]]

Non-impulsive.................. Tracking Exercise-- Surface ship searches for, Mid-frequency surface
Surface (TRACKEX-- tracks, and detects ship sonar, acoustic
Surface). submarine(s). countermeasures, and
high-frequency active
sources.
Non-impulsive.................. Tracking Exercise-- Helicopter searches, Mid-frequency dipping
Helicopter (TRACKEX-- tracks, and detects sonar systems and
Helo). submarine(s). sonobuoys.
Non-impulsive.................. Tracking Exercise-- Maritime patrol aircraft Sonobuoys, such as
Maritime Patrol use sonobuoys to search DICASS sonobuoys.
Aircraft (TRACKEX-- for, detect, and track
MPA). submarine(s).
Non-impulsive.................. Tracking Exercise-- Maritime patrol aircraft mid-frequency MAC
Maritime Patrol crews search for, detect sonobuoys.
Aircraft (MAC and track submarines using
Sonobuoys). MAC sonobuoys.
----------------------------------------------------------------------------------------------------------------
Notes: DICASS = Directional Command Activated Sonobuoy System; MAC=Multistatic Active Coherent

Summary of Impulsive and Non-Impulsive Sources

Table 4 provides a quantitative annual summary of training
activities by sonar and other active acoustic source class analyzed in
the Navy's LOA request.

Table 4--Annual Hours of Sonar and Other Active Acoustic Sources Used During Training Within the Study Area
----------------------------------------------------------------------------------------------------------------
Source class category Source class Units Annual use
----------------------------------------------------------------------------------------------------------------
Mid-Frequency (MF) Active sources from 1 MF1....................... Hours..................... 541
to 10 kHz.
MF3....................... Hours..................... 48
MF4....................... Hours..................... 53
MF5....................... Items..................... 25
MF6....................... Items..................... 21
MF11...................... Hours..................... 78
High-Frequency (HF): Tactical and non- HF1....................... Hours..................... 24
tactical sources that produce signals HF6....................... Hours..................... 80
greater than 10 kHz but less than 100
kHz.
Anti-Submarine Warfare (ASW) Active ASW ASW2...................... Hours..................... 80
sources.
ASW3...................... Hours..................... 546
ASW4...................... Items..................... 4
Torpedoes (TORP) Source classes TORP2..................... Items..................... 5
associated with active acoustic signals
produced by torpedoes.
----------------------------------------------------------------------------------------------------------------

Table 5 provides a quantitative annual summary of training
explosive source classes analyzed in the Navy's LOA request.

Table 5--Annual Number of Training Explosive Source Detonations Used
During Training Within the Study Area
------------------------------------------------------------------------
Annual in-
water
Explosive class net explosive weight (pounds [lb.]) detonations
training
------------------------------------------------------------------------
E5 (> 5-10 lb.)......................................... 112
E6 (> 10-20 lb.)........................................ 2
E7 (> 20-60 lb.)........................................ 4
E8 (> 60-100 lb.)....................................... 6
E9 (> 100-250 lb.)...................................... 142
E10 (> 250-500 lb.)..................................... 32
E11 (> 500-650 lb.)..................................... 2
E12 (> 650-1,000 lb.)................................... 4
------------------------------------------------------------------------

Duration and Location

Training activities would be conducted in the Study Area during two
exercises of up to 21 days each per year (for a total of up to 42 days
per year) to support a major joint training exercise in Alaska and off
the Alaskan coast that involves the Departments of the Navy, the Army
and the Air Force, and the U.S. Coast Guard (Coast Guard). The Service
participants report to a unified or joint commander who coordinates the
activities planned to demonstrate and evaluate the ability of the
services to engage in a conflict and carry out plans in response to a
threat to national security. The exercises would occur between the
months of May and October of each year from 2016 to 2021.
The Study Area (see Figure 1-1 of the LOA application) is entirely
at sea and is composed of the established GOA TMAA and a warning area
in the Gulf of Alaska. The Navy uses ``at-sea'' to include its training
activities in the Study Area that occur (1) on the ocean surface, (2)
beneath the ocean surface, and (3) in the air above the ocean surface.
Navy training activities occurring on or over the land outside the GOA
TMAA are covered under previously prepared environmental documentation
prepared by the U.S. Air Force and the U.S. Army.

Gulf of Alaska Temporary Maritime Activities Area (GOA TMAA)

The GOA TMAA is a temporary area established in conjunction with
the Federal Aviation Administration (FAA) for up to two exercise
periods of up to 21 days each, for a total of 42 days per year, that is
a surface, undersea space, and airspace maneuver area within the Gulf
of Alaska for ships, submarines, and aircraft to conduct required
training activities. The GOA TMAA is a polygon roughly resembling a
rectangle oriented from northwest to southeast,

[[Page 9956]]

approximately 300 nautical miles (nm) in length by 150 nm in width,
located south of Prince William Sound and east of Kodiak Island.

Airspace of the GOA TMAA

The airspace of the GOA TMAA overlies the surface and subsurface
training area and is called an Altitude Reservation (ALTRV). This ALTRV
is a temporary airspace designation, typically requested by the Alaskan
Command (ALCOM) and coordinated through the FAA for the duration of the
exercise. This overwater airspace supports the majority of aircraft
training activities conducted by Navy and Joint aircraft throughout the
joint training exercise. The ALTRV over the GOA TMAA typically extends
from the ocean surface to 60,000 feet (ft.) (18,288 meters [m]) above
mean sea level and encompasses 42,146 square nautical miles (nm\2\) of
airspace. For safety considerations, ALTRV information is sent via
Notice to Airmen (NOTAM)/International NOTAM so that all pilots are
aware of the area and that Air Traffic Control will keep known
Instrument Flight Rules aircraft clear of the area.
Additionally, the GOA TMAA overlies a majority of Warning Area W-
612 (W-612) located over Blying Sound, towards the northwestern
quadrant of the GOA TMAA. When not included as part of the GOA TMAA, W-
612 provides 2,256 nm\2\ of special use airspace for the Air Force and
Coast Guard to fulfill some of their training requirements. Air Force,
Army, National Guard, and Coast Guard activities conducted as part of
at-sea joint training within the GOA TMAA are included in the DSEIS/
OEIS analysis. No Navy training activities analyzed in this proposed
rule occur in the area of W-612 that is outside of the GOA TMAA (see
Figure 1-1 of the LOA application).

Sea and Undersea Space of the GOA TMAA

The GOA TMAA surface and subsurface areas are also depicted in
Figure 1-1 of the LOA application. Total surface area of the GOA TMAA
is 42,146 nm\2\. Due to weather conditions, annual joint training
activities are typically conducted during the summer months (April-
October). The GOA TMAA undersea area lies beneath the surface area as
depicted in Figure 1-1 of the LOA application. The undersea area
extends to the seafloor.
The complex bathymetric and oceanographic conditions, including a
continental shelf, submarine canyons, numerous seamounts, and fresh
water infusions from multiple sources, create a challenging environment
in which to search for and detect submarines in ASW training
activities. In the summer, the GOA TMAA provides a safe cold-water
training environment that resembles other areas where Navy may need to
operate in a real-world scenario.
The GOA TMAA meets large-scale joint exercise training objectives
to support naval and joint operational readiness by providing a
``geographically realistic'' training area for U.S. Pacific Command,
Joint Task Force Commander scenario-based training, and supports the
mission requirement of Alaskan Command (ALCOM) to conduct joint
training for Alaska-based forces. The strategic vision of the
Commander, U.S. Pacific Fleet is that the training area support naval
operational readiness by providing a realistic, live-training
environment for forces assigned to the Pacific Fleet and other users
with the capability and capacity to support current, emerging, and
future training requirements.

Description of Marine Mammals in the Area of the Specified Activities

Marine mammal species known to occur in the Study Area and their
currently recognized stocks are presented in Table 6 consistent with
the NMFS' U.S. Pacific Marine Mammal Stock Assessment Report (Carretta
et al., 2015) and the Alaska Marine Mammal Stock Assessment Report
(Muto and Angliss, 2015). Twenty-two marine mammal species have
confirmed or possible occurrence within or adjacent to the Study Area,
including seven species of baleen whales (mysticetes), eight species of
toothed whales (odontocetes), six species of seals (pinnipeds), and the
sea otter (mustelid). Nine of these species are listed under the ESA:
Blue whale, fin whale, humpback whale, sei whale, sperm whale, gray
whale (Western North Pacific stock), North Pacific right whale, Steller
sea lion (Western U.S. stock), and sea otter. All these species are
managed by NMFS or the U.S. Fish and Wildlife Service (USFWS) in the
U.S. Exclusive Economic Zone (EEZ).
The species carried forward for analysis are those likely to be
found in the Study Area based on the most recent data available, and do
not include stocks or species that may have once inhabited or transited
the area but have not been sighted in recent years (e.g., species which
were extirpated because of factors such as nineteenth and twentieth
century commercial exploitation). Several species that may be present
in the Gulf of Alaska have an extremely low probability of presence in
the Study Area. These species are considered extralimital, meaning
there may be a small number of sighting or stranding records within the
Study Area, but the area of concern is outside the species' range of
normal occurrence. These species include beluga whale (Delphinapterus
leucas), false killer whale (Pseudorca crassidens), short-finned pilot
whale (Globicephala macrorhynchus), northern right whale dolphin
(Lissodelphis borealis), and Risso's dolphin (Grampus griseus), and
have been excluded from subsequent analysis.

Table 6--Marine Mammals With Possible or Confirmed Presence Within the Study Area
--------------------------------------------------------------------------------------------------------------------------------------------------------
Stock abundance \3\ Occurrence in region
Common name Scientific name \1\ Stock \2\ (CV) \4\ ESA/MMPA Status
--------------------------------------------------------------------------------------------------------------------------------------------------------
Order Cetacea
Suborder Mysticeti (baleen whales)
Family Balaenidae (right whales)
--------------------------------------------------------------------------------------------------------------------------------------------------------
North Pacific right whale.......... Eubalaena japonica.... Eastern North Pacific. 31 (0.23)............ Rare................. Endangered/Depleted.
--------------------------------------------------------------------------------------------------------------------------------------------------------
Family Balaenopteridae (rorquals)
--------------------------------------------------------------------------------------------------------------------------------------------------------
Humpback whale..................... Megaptera novaeangliae Central North Pacific. 10,252 (0.042)....... Likely............... Endangered/ Depleted.
Western North Pacific. 893 (0.079).......... Likely............... Endangered/ Depleted.

[[Page 9957]]

Blue whale......................... Balaenoptera musculus. Eastern North Pacific. 1,647 (0.07)......... Seasonal; highest Endangered/ Depleted.
likelihood July to
December.
Central North Pacific. 81 (1.14)............ Seasonal; highest Endangered/ Depleted.
likelihood July to
December.
Fin whale.......................... Balaenoptera physalus. Northeast Pacific..... 1,368 (minimum Likely............... Endangered/ Depleted.
estimate) (n/a).
Sei whale.......................... Balaenoptera borealis. Eastern North Pacific. 126 (0.53)........... Rare................. Endangered/ Depleted.
Minke whale........................ Balaenoptera Alaska................ Not available........ Likely.
acutorostrata.
--------------------------------------------------------------------------------------------------------------------------------------------------------
Family Eschrichtiidae (gray whale)
--------------------------------------------------------------------------------------------------------------------------------------------------------
Gray whale......................... Eschrichtius robustus. Eastern North Pacific. 20,990 (0.05)........ Likely: Highest
numbers during
seasonal migrations.
Western North Pacific. 140 (0.043).......... Rare: Individuals Endangered/ Depleted.
migrate through GOA.
--------------------------------------------------------------------------------------------------------------------------------------------------------
Suborder Odontoceti (toothed whales)
Family Physeteridae (sperm whale)
--------------------------------------------------------------------------------------------------------------------------------------------------------
Sperm whale........................ Physeter macrocephalus North Pacific......... Not available........ Likely; More likely Endangered/ Depleted.
in waters > 1,000 m
depth, most often >
2,000 m.
--------------------------------------------------------------------------------------------------------------------------------------------------------
Family Delphinidae (dolphins)
--------------------------------------------------------------------------------------------------------------------------------------------------------
Killer whale....................... Orcinus orca.......... Alaska Resident....... 2,347 (n/a).......... Likely.
Eastern North Pacific 211: includes known Infrequent: few
Offshore. offshore killer sightings.
whales along the
U.S. west coast,
Canada, and Alaska
(n/a).
AT1 Transient......... 7.................... Rare; more likely
inside Prince
William Sound and
Kenai Fjords.
GOA, Aleutian Island, 587.................. Likely.
and Bering Sea
Transient.
Pacific white[dash]sided dolphin... Lagenorhynchus North Pacific......... 26,880; specific to Likely.
obliquidens. the GOA, not the
management stock (n/
a).
--------------------------------------------------------------------------------------------------------------------------------------------------------
Family Phocoenidae (porpoises)
--------------------------------------------------------------------------------------------------------------------------------------------------------
Harbor porpoise.................... Phocoena phocoena..... GOA................... 31,046 (0.21)........ Likely in nearshore
locations.
Southeast Alaska...... 11,146 (0.24)........ Likely in nearshore
locations.
Dall's porpoise.................... Phocoenoides dalli.... Alaska................ 83,400 (0.097); based Likely.
on survey data from
1987-1991.
--------------------------------------------------------------------------------------------------------------------------------------------------------
Family Ziphiidae (beaked whales)
--------------------------------------------------------------------------------------------------------------------------------------------------------
Cuvier's beaked whale.............. Ziphius cavirostris... Alaska................ Not available........ Likely.
Baird's beaked whale............... Berardius bairdii..... Alaska................ Not available........ Likely.
Stejneger's beaked whale........... Mesoplodon stejnegeri. Alaska................ Not available........ Likely.
--------------------------------------------------------------------------------------------------------------------------------------------------------

[[Page 9958]]

Order Carnivora
Suborder Pinnipedia \5\
Family Otariidae (fur seals and sea lions)
--------------------------------------------------------------------------------------------------------------------------------------------------------
Steller sea lion................... Eumetopias jubatus.... Eastern U.S........... 59,968 (minimum Likely.
estimate) (n/a).
Western U.S........... 49,497 (minimum Likely............... Endangered/ Depleted.
estimate) (n/a).
California sea lion................ Zalophus californianus U.S................... 296,750 (n/a)........ Rare.
Northern fur seal.................. Callorhinus ursinus... Eastern Pacific....... 648,534 (n/a)........ Likely............... Depleted.
--------------------------------------------------------------------------------------------------------------------------------------------------------
Family Phocidae (true seals)
--------------------------------------------------------------------------------------------------------------------------------------------------------
Northern elephant seal............. Mirounga California Breeding... 179,000 (n/a)........ Likely.
angustirostris.
Harbor seal........................ Phoca vitulina........ Aleutian Islands...... 6,431 (n/a).......... Extralimital
Pribilof Islands...... 232 (n/a)............ Extralimital.
Bristol Bay........... 32,350 (n/a)......... Extralimital.
N. Kodiak............. 8,321 (n/a).......... Rare (inshore
waters).
S. Kodiak............. 19,199 (n/a)......... Rare (inshore
waters).
Prince William Sound.. 29,889 (n/a)......... Rare (inshore
waters).
Cook Inlet/Shelikof... 27,386 (n/a)......... Extralimital.
Glacier Bay/Icy Strait 7,210 (n/a).......... Rare (inshore
waters).
Lynn Canal/ Stephens.. 9,478 (n/a).......... Extralimital.
Sitka/Chatham......... 14,855 (n/a)......... Rare (inshore
waters).
Dixon/Cape Decision... 18,105 (n/a)......... Rare (inshore
waters).
Clarence Strait....... 31,634 (n/a)......... Extralimital.
Ribbon seal........................ Histriophoca fasciata. Alaska................ 184,000.............. Rare.
--------------------------------------------------------------------------------------------------------------------------------------------------------
Family Mustelidae (otters) \6\
--------------------------------------------------------------------------------------------------------------------------------------------------------
Northern sea otter................. Enhydra lutris kenyoni Southeast Alaska...... 10,563............... Rare.
Southcentral Alaska... 15,090............... Rare.
Southwest Alaska...... 47,676............... Rare................. Threatened.
--------------------------------------------------------------------------------------------------------------------------------------------------------
\1\ Taxonomy follows Perrin et al. (2009).
\2\ Stock names and abundance estimates from Muto and Angliss (2015) and Carretta et al. (2015) except where noted.
\3\ The stated coefficient of variation (CV) from the NMFS Stock Assessement Reports is an indicator of uncertainty in the abundance estimate and
describes the amount of variation with respect to the population mean. It is expressed as a fraction or sometimes a percentage and can range upward
from zero, indicating no uncertainty, to high values. For example, a CV of 0.85 would indicate high uncertainty in the population estimate. When the
CV exceeds 1.0, the estimate is very uncertain. The uncertainty associated with movements of animals into or out of an area (due to factors such as
availability of prey or changing oceanographic conditions) is much larger than is indicated by the CVs that are given.
\4\ EXTRALIMITAL: There may be a small number of sighting or stranding records, but the area is outside the species range of normal occurrence. RARE:
The distribution of the species is near enough to the area that the species could occur there, or there are a few confirmed sightings. INFREQUENT:
Confirmed, but irregular sightings or acoustic detections. LIKELY: Confirmed and regular sightings or acoustic detections of the species in the area
year-round. SEASONAL: Confirmed and regular sightings or acoustic detections of the species in the area on a seasonal basis.
\5\ There are no data regarding the CV for some of the pinniped species given that abundance is determined by different methods than those used for
cetaceans.
\6\ There are no data regarding the CV for sea otter given that abundance is determined by different methods than those used for cetaceans.
Notes: CV = coefficient of variation, ESA = Endangered Species Act, GOA = Gulf of Alaska, m = meter(s), MMPA = Marine Mammal Protection Act, n/a = not
available, U.S. = United States.

Information on the status, distribution, abundance, and
vocalizations of marine mammal species in the Study Area may be viewed
in Chapter 4 of the LOA application (http://www.nmfs.noaa.gov/pr/permits/incidental/military.htm). Additional information on the general
biology and ecology of marine mammals are included in the GOA DSEIS/
OEIS. In addition, NMFS annually publishes Stock Assessment Reports
(SARs) for all marine mammals in U.S. EEZ waters, including stocks that
occur within the Study Area (U.S. Pacific Marine Mammal Stock
Assessments, Carretta et al., 2015; Alaska Marine Mammal Stock
Assessments, Muto and Angliss, 2015).

Marine Mammal Hearing and Vocalizations

Cetaceans have an auditory anatomy that follows the basic mammalian
pattern, with some changes to adapt to the demands of hearing
underwater. The typical mammalian ear is divided into an outer ear,
middle ear, and inner ear.

[[Page 9959]]

The outer ear is separated from the inner ear by a tympanic membrane,
or eardrum. In terrestrial mammals, the outer ear, eardrum, and middle
ear transmit airborne sound to the inner ear, where the sound waves are
propagated through the cochlear fluid. Since the impedance of water is
close to that of the tissues of a cetacean, the outer ear is not
required to transduce sound energy as it does when sound waves travel
from air to fluid (inner ear). Sound waves traveling through the inner
ear cause the basilar membrane to vibrate. Specialized cells, called
hair cells, respond to the vibration and produce nerve pulses that are
transmitted to the central nervous system. Acoustic energy causes the
basilar membrane in the cochlea to vibrate. Sensory cells at different
positions along the basilar membrane are excited by different
frequencies of sound (Pickles, 1998).
Marine mammal vocalizations often extend both above and below the
range of human hearing; vocalizations with frequencies lower than 20 Hz
are labeled as infrasonic and those higher than 20 kHz as ultrasonic
(National Research Council (NRC), 2003; Figure 4-1). Measured data on
the hearing abilities of cetaceans are sparse, particularly for the
larger cetaceans such as the baleen whales. The auditory thresholds of
some of the smaller odontocetes have been determined in captivity. It
is generally believed that cetaceans should at least be sensitive to
the frequencies of their own vocalizations. Comparisons of the anatomy
of cetacean inner ears and models of the structural properties and the
response to vibrations of the ear's components in different species
provide an indication of likely sensitivity to various sound
frequencies. The ears of small toothed whales are optimized for
receiving high-frequency sound, while baleen whale inner ears are best
in low to infrasonic frequencies (Ketten, 1992; 1997; 1998).
Baleen whale vocalizations are composed primarily of frequencies
below 1 kHz, and some contain fundamental frequencies as low as 16 Hz
(Watkins et al., 1987; Richardson et al., 1995; Rivers, 1997; Moore et
al., 1998; Stafford et al., 1999; Wartzok and Ketten, 1999) but can be
as high as 24 kHz (humpback whale; Au et al., 2006). Clark and Ellison
(2004) suggested that baleen whales use low-frequency sounds not only
for long-range communication, but also as a simple form of echo
ranging, using echoes to navigate and orient relative to physical
features of the ocean. Information on auditory function in baleen
whales is extremely lacking. Sensitivity to low-frequency sound by
baleen whales has been inferred from observed vocalization frequencies,
observed reactions to playback of sounds, and anatomical analyses of
the auditory system. Although there is apparently much variation, the
source levels of most baleen whale vocalizations lie in the range of
150-190 dB re 1 microPascal ([micro]Pa) at 1 m. Low-frequency
vocalizations made by baleen whales and their corresponding auditory
anatomy suggest that they have good low-frequency hearing (Ketten,
2000), although specific data on sensitivity, frequency or intensity
discrimination, or localization abilities are lacking. Marine mammals,
like all mammals, have typical U-shaped audiograms that begin with
relatively low sensitivity (high threshold) at some specified low
frequency with increased sensitivity (low threshold) to a species
specific optimum followed by a generally steep rise at higher
frequencies (high threshold) (Fay, 1988).
The toothed whales produce a wide variety of sounds, which include
species-specific broadband ``clicks'' with peak energy between 10 and
200 kHz, individually variable ``burst pulse'' click trains, and
constant frequency or frequency-modulated (FM) whistles ranging from 4
to 16 kHz (Wartzok and Ketten, 1999). The general consensus is that the
tonal vocalizations (whistles) produced by toothed whales play an
important role in maintaining contact between dispersed individuals,
while broadband clicks are used during echolocation (Wartzok and
Ketten, 1999). Burst pulses have also been strongly implicated in
communication, with some scientists suggesting that they play an
important role in agonistic encounters (McCowan and Reiss, 1995), while
others have proposed that they represent ``emotive'' signals in a
broader sense, possibly representing graded communication signals
(Herzing, 1996). Sperm whales, however, are known to produce only
clicks, which are used for both communication and echolocation
(Whitehead, 2003). Most of the energy of toothed whale social
vocalizations is concentrated near 10 kHz, with source levels for
whistles as high as 100 to 180 dB re 1 [micro]Pa at 1 m (Richardson et
al., 1995). No odontocete has been shown audiometrically to have acute
hearing (<80 dB re 1 [micro]Pa) below 500 Hz (DoN, 2001). Sperm whales
produce clicks, which may be used to echolocate (Mullins et al., 1988),
with a frequency range from less than 100 Hz to 30 kHz and source
levels up to 230 dB re 1 [micro]Pa 1 m or greater (Mohl et al., 2000).

Brief Background on Sound

An understanding of the basic properties of underwater sound is
necessary to comprehend many of the concepts and analyses presented in
this proposed rule. A summary is included below.
Sound is a wave of pressure variations propagating through a medium
(e.g., water). Pressure variations are created by compressing and
relaxing the medium. Sound measurements can be expressed in two forms:
Intensity and pressure. Acoustic intensity is the average rate of
energy transmitted through a unit area in a specified direction and is
expressed in watts per square meter (W/m\2\). Acoustic intensity is
rarely measured directly, but rather from ratios of pressures; the
standard reference pressure for underwater sound is 1 [micro]Pa; for
airborne sound, the standard reference pressure is 20 [micro]Pa
(Richardson et al., 1995).
Acousticians have adopted a logarithmic scale for sound
intensities, which is denoted in decibels (dB). Decibel measurements
represent the ratio between a measured pressure value and a reference
pressure value (in this case 1 [micro]Pa or, for airborne sound, 20
[micro]Pa). The logarithmic nature of the scale means that each 10-dB
increase is a ten-fold increase in acoustic power (and a 20-dB increase
is then a 100-fold increase in power; and a 30-dB increase is a 1,000-
fold increase in power). A ten-fold increase in acoustic power does not
mean that the sound is perceived as being ten times louder, however.
Humans perceive a 10-dB increase in sound level as a doubling of
loudness, and a 10-dB decrease in sound level as a halving of loudness.
The term ``sound pressure level'' implies a decibel measure and a
reference pressure that is used as the denominator of the ratio.
Throughout this proposed rule, NMFS uses 1 [micro]Pa (denoted re:
1[micro]Pa) as a standard reference pressure unless noted otherwise.
It is important to note that decibel values underwater and decibel
values in air are not the same (different reference pressures and
densities/sound speeds between media) and should not be directly
compared. Because of the different densities of air and water and the
different decibel standards (i.e., reference pressures) in air and
water, a sound with the same level in air and in water would be
approximately 62 dB lower in air. Thus, a sound that measures 160 dB
(re 1 [micro]Pa) underwater would have the same approximate effective
level as a sound that is 98 dB (re 20 [micro]Pa) in air.

[[Page 9960]]

Sound frequency is measured in cycles per second, or Hertz
(abbreviated Hz), and is analogous to musical pitch; high-pitched
sounds contain high frequencies and low-pitched sounds contain low
frequencies. Natural sounds in the ocean span a huge range of
frequencies: From earthquake noise at 5 Hz to harbor porpoise clicks at
150,000 Hz (150 kHz). These sounds are so low or so high in pitch that
humans cannot even hear them; acousticians call these infrasonic
(typically below 20 Hz) and ultrasonic (typically above 20,000 Hz)
sounds, respectively. A single sound may be made up of many different
frequencies together. Sounds made up of only a small range of
frequencies are called ``narrowband'', and sounds with a broad range of
frequencies are called ``broadband''; explosives are an example of a
broadband sound source and active tactical sonars are an example of a
narrowband sound source.
When considering the influence of various kinds of sound on the
marine environment, it is necessary to understand that different kinds
of marine life are sensitive to different frequencies of sound. Current
data indicate that not all marine mammal species have equal hearing
capabilities (Richardson et al., 1995; Southall et al., 1997; Wartzok
and Ketten, 1999; Au and Hastings, 2008).
Southall et al. (2007) designated ``functional hearing groups'' for
marine mammals based on available behavioral data; audiograms derived
from auditory evoked potentials; anatomical modeling; and other data.
Southall et al. (2007) also estimated the lower and upper frequencies
of functional hearing for each group. However, animals are less
sensitive to sounds at the outer edges of their functional hearing
range and are more sensitive to a range of frequencies within the
middle of their functional hearing range. Note that direct measurements
of hearing sensitivity do not exist for all species of marine mammals,
including low-frequency cetaceans. The functional hearing groups and
the associated frequencies developed by Southall et al. (2007) were
revised by Finneran and Jenkins (2012) and have been further modified
by NOAA. Table 7 provides a summary of sound production and general
hearing capabilities for marine mammal species (note that values in
this table are not meant to reflect absolute possible maximum ranges,
rather they represent the best known ranges of each functional hearing
group). For purposes of the analysis in this proposed rule, marine
mammals are arranged into the following functional hearing groups based
on their generalized hearing sensitivities: High-frequency cetaceans,
mid-frequency cetaceans, low-frequency cetaceans (mysticetes), phocids
(true seals), otariids (sea lion and fur seals), and mustelids (sea
otters). A detailed discussion of the functional hearing groups can be
found in Southall et al. (2007) and Finneran and Jenkins (2012).

Table 7--Marine Mammal Functional Hearing Groups
------------------------------------------------------------------------
Functional hearing group Functional hearing range *
------------------------------------------------------------------------
Low-frequency (LF) cetaceans (baleen 7 Hz to 25 kHz.
whales).
Mid-frequency (MF) cetaceans 150 Hz to 160 kHz.
(dolphins, toothed whales, beaked
whales, bottlenose whales).
High-frequency (HF) cetaceans (true 200 Hz to 180 kHz.
porpoises, Kogia, river dolphins,
cephalorhynchid, Lagenorhynchus
cruciger & L. australis).
Phocid pinnipeds (underwater) (true 75 Hz to 100 kHz.
seals).
Otariid pinnipeds (underwater) (sea 100 Hz to 48 kHz.
lions and fur seals).
------------------------------------------------------------------------
Adapted and derived from Southall et al. (2007)
* Represents frequency band of hearing for entire group as a composite
(i.e., all species within the group), where individual species'
hearing ranges are typically not as broad. Functional hearing is
defined as the range of frequencies a group hears without
incorporating non-acoustic mechanisms (Wartzok and Ketten, 1999). This
is ~60 to ~70 dB above best hearing sensitivity (Southall et al.,
2007) for all functional hearing groups except LF cetaceans, where no
direct measurements on hearing are available. For LF cetaceans, the
lower range is based on recommendations from Southall et al., 2007 and
the upper range is based on information on inner ear anatomy and
vocalizations.

When sound travels (propagates) from its source, its loudness
decreases as the distance traveled by the sound increases. Thus, the
loudness of a sound at its source is higher than the loudness of that
same sound a kilometer away. Acousticians often refer to the loudness
of a sound at its source (typically referenced to one meter from the
source) as the source level and the loudness of sound elsewhere as the
received level (i.e., typically the receiver). For example, a humpback
whale 3 km from a device that has a source level of 230 dB may only be
exposed to sound that is 160 dB loud, depending on how the sound
travels through water (e.g., spherical spreading [3 dB reduction with
doubling of distance] was used in this example). As a result, it is
important to understand the difference between source levels and
received levels when discussing the loudness of sound in the ocean or
its impacts on the marine environment.
As sound travels from a source, its propagation in water is
influenced by various physical characteristics, including water
temperature, depth, salinity, and surface and bottom properties that
cause refraction, reflection, absorption, and scattering of sound
waves. Oceans are not homogeneous and the contribution of each of these
individual factors is extremely complex and interrelated. The physical
characteristics that determine the sound's speed through the water will
change with depth, season, geographic location, and with time of day
(as a result, in actual active sonar operations, crews will measure
oceanic conditions, such as sea water temperature and depth, to
calibrate models that determine the path the sonar signal will take as
it travels through the ocean and how strong the sound signal will be at
a given range along a particular transmission path). As sound travels
through the ocean, the intensity associated with the wavefront
diminishes, or attenuates. This decrease in intensity is referred to as
propagation loss, also commonly called transmission loss.

Metrics Used in This Proposed Rule

This section includes a brief explanation of the two sound
measurements (sound pressure level (SPL) and sound exposure level
(SEL)) frequently used to describe sound levels in the discussions of
acoustic effects in this proposed rule.
Sound pressure level (SPL)--Sound pressure is the sound force per
unit area, and is usually measured in micropascals ([micro]Pa), where 1
Pa is the pressure resulting from a force of one newton exerted over an
area of one square meter. SPL is expressed as the

[[Page 9961]]

ratio of a measured sound pressure and a reference level.

SPL (in dB) = 20 log (pressure/reference pressure)

The commonly used reference pressure level in underwater acoustics
is 1 [micro]Pa, and the units for SPLs are dB re: 1 [micro]Pa. SPL is
an instantaneous pressure measurement and can be expressed as the peak,
the peak-peak, or the root mean square (rms). Root mean square
pressure, which is the square root of the arithmetic average of the
squared instantaneous pressure values, is typically used in discussions
of the effects of sounds on vertebrates and all references to SPL in
this proposed rule refer to the root mean square. SPL does not take the
duration of exposure into account. SPL is the applicable metric used in
the risk continuum, which is used to estimate behavioral harassment
takes (see Level B Harassment Risk Function (Behavioral Harassment)
Section).
Sound exposure level (SEL)--SEL is an energy metric that integrates
the squared instantaneous sound pressure over a stated time interval.
The units for SEL are dB re: 1 [micro]Pa\2\-s. Below is a simplified
formula for SEL.

SEL = SPL + 10log (duration in seconds)

As applied to active sonar, the SEL includes both the SPL of a
sonar ping and the total duration. Longer duration pings and/or pings
with higher SPLs will have a higher SEL. If an animal is exposed to
multiple pings, the SEL in each individual ping is summed to calculate
the cumulative SEL. The cumulative SEL depends on the SPL, duration,
and number of pings received. The thresholds that NMFS uses to indicate
at what received level the onset of temporary threshold shift (TTS) and
permanent threshold shift (PTS) in hearing are likely to occur are
expressed as cumulative SEL.

Potential Effects of Specified Activities on Marine Mammals

The Navy has requested authorization for the take of marine mammals
that may occur incidental to training activities in the Study Area. The
Navy has analyzed potential impacts to marine mammals from impulsive
and non-impulsive sound sources.
Other potential impacts to marine mammals from training activities
in the Study Area were analyzed in the GOA DSEIS/OEIS, in consultation
with NMFS as a cooperating agency, and determined to be unlikely to
result in marine mammal harassment. Therefore, the Navy has not
requested authorization for take of marine mammals that might occur
incidental to other components of their proposed activities. In this
proposed rule, NMFS analyzes the potential effects on marine mammals
from exposure to non-impulsive sound sources (sonar and other active
acoustic sources) and impulsive sound sources (underwater detonations).
For the purpose of MMPA authorizations, NMFS' effects assessments
serve four primary purposes: (1) To prescribe the permissible methods
of taking (i.e., Level B harassment (behavioral harassment), Level A
harassment (injury), or mortality, including an identification of the
number and types of take that could occur by harassment or mortality)
and to prescribe other means of effecting the least practicable adverse
impact on such species or stock and its habitat (i.e., mitigation); (2)
to determine whether the specified activity would have a negligible
impact on the affected species or stocks of marine mammals (based on
the likelihood that the activity would adversely affect the species or
stock through effects on annual rates of recruitment or survival); (3)
to determine whether the specified activity would have an unmitigable
adverse impact on the availability of the species or stock(s) for
subsistence uses; and (4) to prescribe requirements pertaining to
monitoring and reporting.
This section focuses qualitatively on the different ways that non-
impulsive and impulsive sources may affect marine mammals (some of
which NMFS would not classify as harassment). Then the Estimated Take
of Marine Mammals section discusses how the potential effects of non-
impulsive and impulsive sources on marine mammals will be related to
the MMPA definitions of Level A and Level B Harassment, and attempts to
quantify those effects.

Non-impulsive Sources

Direct Physiological Effects

Based on the literature, there are two basic ways that non-
impulsive sources might directly result in physical trauma or damage:
Noise-induced loss of hearing sensitivity (more commonly-called
``threshold shift'') and acoustically mediated bubble growth.
Separately, an animal's behavioral reaction to an acoustic exposure
might lead to physiological effects that might ultimately lead to
injury or death, which is discussed later in the Stranding section.
Threshold Shift (noise-induced loss of hearing)--When animals
exhibit reduced hearing sensitivity (i.e., sounds must be louder for an
animal to detect them) following exposure to an intense sound or sound
for long duration, it is referred to as a noise-induced threshold shift
(TS). An animal can experience temporary threshold shift (TTS) or
permanent threshold shift (PTS). TTS can last from minutes or hours to
days (i.e., there is complete recovery), can occur in specific
frequency ranges (i.e., an animal might only have a temporary loss of
hearing sensitivity between the frequencies of 1 and 10 kHz), and can
be of varying amounts (for example, an animal's hearing sensitivity
might be reduced initially by only 6 dB or reduced by 30 dB). PTS is
permanent, but some recovery is possible. PTS can also occur in a
specific frequency range and amount, as mentioned above for TTS.
The following physiological mechanisms are thought to play a role
in inducing auditory TS: Effects to sensory hair cells in the inner ear
that reduce their sensitivity, modification of the chemical environment
within the sensory cells, residual muscular activity in the middle ear,
displacement of certain inner ear membranes, increased blood flow, and
post-stimulatory reduction in both efferent and sensory neural output
(Southall et al., 2007). The amplitude, duration, frequency, temporal
pattern, and energy distribution of sound exposure all can affect the
amount of associated TS and the frequency range in which it occurs. As
amplitude and duration of sound exposure increase, so, generally, does
the amount of TS, along with the recovery time. For intermittent
sounds, less TS could occur than compared to a continuous exposure with
the same energy (some recovery could occur between intermittent
exposures depending on the duty cycle between sounds) (Kryter et al.,
1966; Ward, 1997). For example, one short but loud (higher SPL) sound
exposure may induce the same impairment as one longer but softer sound,
which in turn may cause more impairment than a series of several
intermittent softer sounds with the same total energy (Ward, 1997).
Additionally, though TTS is temporary, prolonged exposure to sounds
strong enough to elicit TTS, or shorter-term exposure to sound levels
well above the TTS threshold, can cause PTS, at least in terrestrial
mammals (Kryter, 1985). Although in the case of mid- and high-frequency
active sonar (MFAS/HFAS), animals are not expected to be exposed to
levels high enough or durations long enough to result in PTS.
PTS is considered auditory injury (Southall et al., 2007).
Irreparable damage to the inner or outer cochlear hair cells may cause
PTS; however,

[[Page 9962]]

other mechanisms are also involved, such as exceeding the elastic
limits of certain tissues and membranes in the middle and inner ears
and resultant changes in the chemical composition of the inner ear
fluids (Southall et al., 2007).
Although the published body of scientific literature contains
numerous theoretical studies and discussion papers on hearing
impairments that can occur with exposure to a loud sound, only a few
studies provide empirical information on the levels at which noise-
induced loss in hearing sensitivity occurs in nonhuman animals. For
marine mammals, published data are limited to the captive bottlenose
dolphin, beluga, harbor porpoise, and Yangtze finless porpoise
(Finneran et al., 2000, 2002b, 2003, 2005a, 2007, 2010a, 2010b;
Finneran and Schlundt, 2010; Lucke et al., 2009; Mooney et al., 2009a,
2009b; Popov et al., 2011a, 2011b; Kastelein et al., 2012a; Schlundt et
al., 2000; Nachtigall et al., 2003, 2004). For pinnipeds in water, data
are limited to measurements of TTS in harbor seals, an elephant seal,
and California sea lions (Kastak et al., 1999, 2005; Kastelein et al.,
2012b).
Marine mammal hearing plays a critical role in communication with
conspecifics, and interpretation of environmental cues for purposes
such as predator avoidance and prey capture. Depending on the degree
(elevation of threshold in dB), duration (i.e., recovery time), and
frequency range of TTS, and the context in which it is experienced, TTS
can have effects on marine mammals ranging from discountable to serious
(similar to those discussed in auditory masking, below). For example, a
marine mammal may be able to readily compensate for a brief, relatively
small amount of TTS in a non-critical frequency range that occurs
during a time where ambient noise is lower and there are not as many
competing sounds present. Alternatively, a larger amount and longer
duration of TTS sustained during time when communication is critical
for successful mother/calf interactions could have more serious
impacts. Also, depending on the degree and frequency range, the effects
of PTS on an animal could range in severity, although it is considered
generally more serious because it is a permanent condition. Of note,
reduced hearing sensitivity as a simple function of aging has been
observed in marine mammals, as well as humans and other taxa (Southall
et al., 2007), so one can infer that strategies exist for coping with
this condition to some degree, though likely not without cost.
Acoustically Mediated Bubble Growth--One theoretical cause of
injury to marine mammals is rectified diffusion (Crum and Mao, 1996),
the process of increasing the size of a bubble by exposing it to a
sound field. This process could be facilitated if the environment in
which the ensonified bubbles exist is supersaturated with gas.
Repetitive diving by marine mammals can cause the blood and some
tissues to accumulate gas to a greater degree than is supported by the
surrounding environmental pressure (Ridgway and Howard, 1979). The
deeper and longer dives of some marine mammals (for example, beaked
whales) are theoretically predicted to induce greater supersaturation
(Houser et al., 2001b). If rectified diffusion were possible in marine
mammals exposed to high-level sound, conditions of tissue
supersaturation could theoretically speed the rate and increase the
size of bubble growth. Subsequent effects due to tissue trauma and
emboli would presumably mirror those observed in humans suffering from
decompression sickness.
It is unlikely that the short duration of sonar pings would be long
enough to drive bubble growth to any substantial size, if such a
phenomenon occurs. However, an alternative but related hypothesis has
also been suggested: Stable bubbles could be destabilized by high-level
sound exposures such that bubble growth then occurs through static
diffusion of gas out of the tissues. In such a scenario the marine
mammal would need to be in a gas-supersaturated state for a long enough
period of time for bubbles to become of a problematic size. Recent
research with ex vivo supersaturated bovine tissues suggested that, for
a 37 kHz signal, a sound exposure of approximately 215 dB referenced to
(re) 1 [mu]Pa would be required before microbubbles became destabilized
and grew (Crum et al., 2005). Assuming spherical spreading loss and a
nominal sonar source level of 235 dB re 1 [mu]Pa at 1 m, a whale would
need to be within 10 m (33 ft.) of the sonar dome to be exposed to such
sound levels. Furthermore, tissues in the study were supersaturated by
exposing them to pressures of 400-700 kilopascals for periods of hours
and then releasing them to ambient pressures. Assuming the
equilibration of gases with the tissues occurred when the tissues were
exposed to the high pressures, levels of supersaturation in the tissues
could have been as high as 400-700 percent. These levels of tissue
supersaturation are substantially higher than model predictions for
marine mammals (Houser et al., 2001; Saunders et al., 2008). It is
improbable that this mechanism is responsible for stranding events or
traumas associated with beaked whale strandings. Both the degree of
supersaturation and exposure levels observed to cause microbubble
destabilization are unlikely to occur, either alone or in concert.
Yet another hypothesis (decompression sickness) has speculated that
rapid ascent to the surface following exposure to a startling sound
might produce tissue gas saturation sufficient for the evolution of
nitrogen bubbles (Jepson et al., 2003; Fernandez et al., 2005;
Fern[aacute]ndez et al., 2012). In this scenario, the rate of ascent
would need to be sufficiently rapid to compromise behavioral or
physiological protections against nitrogen bubble formation.
Alternatively, Tyack et al. (2006) studied the deep diving behavior of
beaked whales and concluded that: ``Using current models of breath-hold
diving, we infer that their natural diving behavior is inconsistent
with known problems of acute nitrogen supersaturation and embolism.''
Collectively, these hypotheses can be referred to as ``hypotheses of
acoustically mediated bubble growth.''
Although theoretical predictions suggest the possibility for
acoustically mediated bubble growth, there is considerable disagreement
among scientists as to its likelihood (Piantadosi and Thalmann, 2004;
Evans and Miller, 2003). Crum and Mao (1996) hypothesized that received
levels would have to exceed 190 dB in order for there to be the
possibility of significant bubble growth due to supersaturation of
gases in the blood (i.e., rectified diffusion). More recent work
conducted by Crum et al. (2005) demonstrated the possibility of
rectified diffusion for short duration signals, but at SELs and tissue
saturation levels that are highly improbable to occur in diving marine
mammals. To date, energy levels (ELs) predicted to cause in vivo bubble
formation within diving cetaceans have not been evaluated (NOAA,
2002b). Although it has been argued that traumas from some recent
beaked whale strandings are consistent with gas emboli and bubble-
induced tissue separations (Jepson et al., 2003), there is no
conclusive evidence of this. However, Jepson et al. (2003, 2005) and
Fernandez et al. (2004, 2005, 2012) concluded that in vivo bubble
formation, which may be exacerbated by deep, long-duration, repetitive
dives may explain why beaked whales appear to be particularly
vulnerable to sonar exposures. Further investigation is needed to
further assess the potential

[[Page 9963]]

validity of these hypotheses. More information regarding hypotheses
that attempt to explain how behavioral responses to non-impulsive
sources can lead to strandings is included in the Stranding and
Mortality section.

Acoustic Masking

Marine mammals use acoustic signals for a variety of purposes,
which differ among species, but include communication between
individuals, navigation, foraging, reproduction, and learning about
their environment (Erbe and Farmer, 2000; Tyack, 2000). Masking, or
auditory interference, generally occurs when sounds in the environment
are louder than and of a similar frequency to, auditory signals an
animal is trying to receive. Masking is a phenomenon that affects
animals that are trying to receive acoustic information about their
environment, including sounds from other members of their species,
predators, prey, and sounds that allow them to orient in their
environment. Masking these acoustic signals can disturb the behavior of
individual animals, groups of animals, or entire populations.
The extent of the masking interference depends on the spectral,
temporal, and spatial relationships between the signals an animal is
trying to receive and the masking noise, in addition to other factors.
In humans, significant masking of tonal signals occurs as a result of
exposure to noise in a narrow band of similar frequencies. As the sound
level increases, though, the detection of frequencies above those of
the masking stimulus decreases also. This principle is expected to
apply to marine mammals as well because of common biomechanical
cochlear properties across taxa.
Richardson et al. (1995b) argued that the maximum radius of
influence of an industrial noise (including broadband low-frequency
sound transmission) on a marine mammal is the distance from the source
to the point at which the noise can barely be heard. This range is
determined by either the hearing sensitivity of the animal or the
background noise level present. Industrial masking is most likely to
affect some species' ability to detect communication calls and natural
sounds (i.e., surf noise, prey noise, etc.; Richardson et al., 1995).
The echolocation calls of toothed whales are subject to masking by
high-frequency sound. Human data indicate low-frequency sound can mask
high-frequency sounds (i.e., upward masking). Studies on captive
odontocetes by Au et al. (1974, 1985, 1993) indicate that some species
may use various processes to reduce masking effects (e.g., adjustments
in echolocation call intensity or frequency as a function of background
noise conditions). There is also evidence that the directional hearing
abilities of odontocetes are useful in reducing masking at the high-
frequencies these cetaceans use to echolocate, but not at the low-to-
moderate frequencies they use to communicate (Zaitseva et al., 1980). A
recent study by Nachtigall and Supin (2008) showed that false killer
whales adjust their hearing to compensate for ambient sounds and the
intensity of returning echolocation signals.
The functional hearing ranges of mysticetes, odontocetes, and
pinnipeds underwater all encompass the frequencies of the sonar sources
used in the Navy's low-frequency (LF)/MFAS/HFAS training exercises.
Additionally, almost all species' vocal repertoires span across the
frequencies of these sonar sources used by the Navy. The closer the
characteristics of the masking signal to the signal of interest, the
more likely masking is to occur. For hull-mounted sonar, which accounts
for a large number of the takes of marine mammals (because of the
source strength and number of hours it is conducted), the pulse length
and low duty cycle of the MFAS/HFAS signal makes it less likely that
masking would occur as a result.

Impaired Communication

In addition to making it more difficult for animals to perceive
acoustic cues in their environment, anthropogenic sound presents
separate challenges for animals that are vocalizing. When they
vocalize, animals are aware of environmental conditions that affect the
``active space'' of their vocalizations, which is the maximum area
within which their vocalizations can be detected before it drops to the
level of ambient noise (Brenowitz, 2004; Brumm et al., 2004; Lohr et
al., 2003). Animals are also aware of environmental conditions that
affect whether listeners can discriminate and recognize their
vocalizations from other sounds, which is more important than simply
detecting that a vocalization is occurring (Brenowitz, 1982; Brumm et
al., 2004; Dooling, 2004, Marten and Marler, 1977; Patricelli et al.,
2006). Most animals that vocalize have evolved with an ability to make
adjustments to their vocalizations to increase the signal-to-noise
ratio, active space, and recognizability/distinguishability of their
vocalizations in the face of temporary changes in background noise
(Brumm et al., 2004; Patricelli et al., 2006). Vocalizing animals can
make adjustments to vocalization characteristics such as the frequency
structure, amplitude, temporal structure, and temporal delivery.
Many animals will combine several of these strategies to compensate
for high levels of background noise. Anthropogenic sounds that reduce
the signal-to-noise ratio of animal vocalizations, increase the masked
auditory thresholds of animals listening for such vocalizations, or
reduce the active space of an animal's vocalizations impair
communication between animals. Most animals that vocalize have evolved
strategies to compensate for the effects of short-term or temporary
increases in background or ambient noise on their songs or calls.
Although the fitness consequences of these vocal adjustments remain
unknown, like most other trade-offs animals must make, some of these
strategies probably come at a cost (Patricelli et al., 2006). For
example, vocalizing more loudly in noisy environments may have
energetic costs that decrease the net benefits of vocal adjustment and
alter a bird's energy budget (Brumm, 2004; Wood and Yezerinac, 2006).
Shifting songs and calls to higher frequencies may also impose
energetic costs (Lambrechts, 1996).

Stress Responses

Classic stress responses begin when an animal's central nervous
system perceives a potential threat to its homeostasis. That perception
triggers stress responses regardless of whether a stimulus actually
threatens the animal; the mere perception of a threat is sufficient to
trigger a stress response (Moberg, 2000; Sapolsky et al., 2005; Seyle,
1950). Once an animal's central nervous system perceives a threat, it
mounts a biological response or defense that consists of a combination
of the four general biological defense responses: Behavioral responses,
autonomic nervous system responses, neuroendocrine responses, or immune
responses.
In the case of many stressors, an animal's first and sometimes most
economical (in terms of biotic costs) response is behavioral avoidance
of the potential stressor or avoidance of continued exposure to a
stressor. An animal's second line of defense to stressors involves the
sympathetic part of the autonomic nervous system and the classical
``fight or flight'' response which includes the cardiovascular system,
the gastrointestinal system, the exocrine glands, and the adrenal
medulla to produce changes in heart rate, blood pressure, and
gastrointestinal activity that humans commonly

[[Page 9964]]

associate with ``stress.'' These responses have a relatively short
duration and may or may not have significant long-term effect on an
animal's welfare.
An animal's third line of defense to stressors involves its
neuroendocrine systems; the system that has received the most study has
been the hypothalmus-pituitary-adrenal system (also known as the HPA
axis in mammals or the hypothalamus-pituitary-interrenal axis in fish
and some reptiles). Unlike stress responses associated with the
autonomic nervous system, virtually all neuro-endocrine functions that
are affected by stress--including immune competence, reproduction,
metabolism, and behavior--are regulated by pituitary hormones. Stress-
induced changes in the secretion of pituitary hormones have been
implicated in failed reproduction (Moberg, 1987; Rivier, 1995), altered
metabolism (Elasser et al., 2000), reduced immune competence (Blecha,
2000), and behavioral disturbance. Increases in the circulation of
glucocorticosteroids (cortisol, corticosterone, and aldosterone in
marine mammals; see Romano et al., 2004) have been equated with stress
for many years.
The primary distinction between stress (which is adaptive and does
not normally place an animal at risk) and distress is the biotic cost
of the response. During a stress response, an animal uses glycogen
stores that can be quickly replenished once the stress is alleviated.
In such circumstances, the cost of the stress response would not pose a
risk to the animal's welfare. However, when an animal does not have
sufficient energy reserves to satisfy the energetic costs of a stress
response, energy resources must be diverted from other biotic function,
which impairs those functions that experience the diversion. For
example, when mounting a stress response diverts energy away from
growth in young animals, those animals may experience stunted growth.
When mounting a stress response diverts energy from a fetus, an
animal's reproductive success and its fitness will suffer. In these
cases, the animals will have entered a pre-pathological or pathological
state which is called ``distress'' (Seyle, 1950) or ``allostatic
loading'' (McEwen and Wingfield, 2003). This pathological state will
last until the animal replenishes its biotic reserves sufficient to
restore normal function. Note that these examples involved a long-term
(days or weeks) stress response exposure to stimuli.
Relationships between these physiological mechanisms, animal
behavior, and the costs of stress responses have also been documented
fairly well through controlled experiments; because this physiology
exists in every vertebrate that has been studied, it is not surprising
that stress responses and their costs have been documented in both
laboratory and free-living animals (for examples see, Holberton et al.,
1996; Hood et al., 1998; Jessop et al., 2003; Krausman et al., 2004;
Lankford et al., 2005; Reneerkens et al., 2002; Thompson and Hamer,
2000). Information has also been collected on the physiological
responses of marine mammals to exposure to anthropogenic sounds (Fair
and Becker, 2000; Romano et al., 2002; Wright et al., 2008). Various
efforts have been undertaken to investigate the impact from vessels
(both whale-watching and general vessel traffic noise), and
demonstrated impacts do occur (Bain, 2002; Erbe, 2002; Noren et al.,
2009; Williams et al., 2006, 2009, 2014a, 2014b; Read et al., 2014;
Rolland et al., 2012; Pirotta et al., 2015). This body of research for
the most part has investigated impacts associated with the presence of
chronic stressors, which differ significantly from the proposed Navy
training activities in the GOA TMAA. For example, in an analysis of
energy costs to killer whales, Williams et al. (2009) suggested that
whale-watching in Canada's Johnstone Strait resulted in lost feeding
opportunities due to vessel disturbance, which could carry higher costs
than other measures of behavioral change might suggest. Ayres et al.
(2012) recently reported on research in the Salish Sea (Washington
state) involving the measurement of southern resident killer whale
fecal hormones to assess two potential threats to the species recovery:
Lack of prey (salmon) and impacts to behavior from vessel traffic.
Ayres et al. (2012) suggested that the lack of prey overshadowed any
population-level physiological impacts on southern resident killer
whales from vessel traffic. Rolland et al. (2012) found that noise
reduction from reduced ship traffic in the Bay of Fundy was associated
with decreased stress in North Atlantic right whales. In a conceptual
model developed by the Population Consequences of Acoustic Disturbance
(PCAD) working group, serum hormones were identified as possible
indicators of behavioral effects that are translated into altered rates
of reproduction and mortality. The Office of Naval Research hosted a
workshop (Effects of Stress on Marine Mammals Exposed to Sound) in 2009
that focused on this very topic (ONR, 2009).
Studies of other marine animals and terrestrial animals would also
lead us to expect some marine mammals to experience physiological
stress responses and, perhaps, physiological responses that would be
classified as ``distress'' upon exposure to high frequency, mid-
frequency and low-frequency sounds. For example, Jansen (1998) reported
on the relationship between acoustic exposures and physiological
responses that are indicative of stress responses in humans (for
example, elevated respiration and increased heart rates). Jones (1998)
reported on reductions in human performance when faced with acute,
repetitive exposures to acoustic disturbance. Trimper et al. (1998)
reported on the physiological stress responses of osprey to low-level
aircraft noise while Krausman et al. (2004) reported on the auditory
and physiological stress responses of endangered Sonoran pronghorn to
military overflights. Smith et al. (2004a, 2004b), for example,
identified noise-induced physiological transient stress responses in
hearing-specialist fish (i.e., goldfish) that accompanied short- and
long-term hearing losses. Welch and Welch (1970) reported physiological
and behavioral stress responses that accompanied damage to the inner
ears of fish and several mammals.
Hearing is one of the primary senses marine mammals use to gather
information about their environment and to communicate with
conspecifics. Although empirical information on the relationship
between sensory impairment (TTS, PTS, and acoustic masking) on marine
mammals remains limited, it seems reasonable to assume that reducing an
animal's ability to gather information about its environment and to
communicate with other members of its species would be stressful for
animals that use hearing as their primary sensory mechanism. Therefore,
we assume that acoustic exposures sufficient to trigger onset PTS or
TTS would be accompanied by physiological stress responses because
terrestrial animals exhibit those responses under similar conditions
(NRC, 2003). More importantly, marine mammals might experience stress
responses at received levels lower than those necessary to trigger
onset TTS. Based on empirical studies of the time required to recover
from stress responses (Moberg, 2000), we also assume that stress
responses are likely to persist beyond the time interval required for
animals to recover from TTS and might result in pathological and pre-
pathological states that would

[[Page 9965]]

be as significant as behavioral responses to TTS.

Behavioral Disturbance

Behavioral responses to sound are highly variable and context-
specific. Many different variables can influence an animal's perception
of and response to (nature and magnitude) an acoustic event. An
animal's prior experience with a sound or sound source affects whether
it is less likely (habituation) or more likely (sensitization) to
respond to certain sounds in the future (animals can also be innately
pre-disposed to respond to certain sounds in certain ways) (Southall et
al., 2007). Related to the sound itself, the perceived nearness of the
sound, bearing of the sound (approaching vs. retreating), similarity of
a sound to biologically relevant sounds in the animal's environment
(i.e., calls of predators, prey, or conspecifics), and familiarity of
the sound may affect the way an animal responds to the sound (Southall
et al., 2007). Individuals (of different age, gender, reproductive
status, etc.) among most populations will have variable hearing
capabilities, and differing behavioral sensitivities to sounds that
will be affected by prior conditioning, experience, and current
activities of those individuals. Often, specific acoustic features of
the sound and contextual variables (i.e., proximity, duration, or
recurrence of the sound or the current behavior that the marine mammal
is engaged in or its prior experience), as well as entirely separate
factors such as the physical presence of a nearby vessel, may be more
relevant to the animal's response than the received level alone.
Ellison et al. (2012) outlined an approach to assessing the effects of
sound on marine mammals that incorporates contextual-based factors.
They recommend considering not just the received level of sound, but
also the activity the animal is engaged in at the time the sound is
received, the nature and novelty of the sound (i.e., is this a new
sound from the animal's perspective), and the distance between the
sound source and the animal. They submit that this ``exposure
context,'' as described, greatly influences the type of behavioral
response exhibited by the animal. This sort of contextual information
is challenging to predict with accuracy for ongoing activities that
occur over large scales and large periods of time. While contextual
elements of this sort are typically not included in calculations to
quantify take, they are often considered qualitatively (where
supporting information is available) in the subsequent analysis that
seeks to assess the likely consequences of sound exposures above a
certain level.
Exposure of marine mammals to sound sources can result in no
response or responses including, but not limited to: Increased
alertness; orientation or attraction to a sound source; vocal
modifications; cessation of feeding; cessation of social interaction;
alteration of movement or diving behavior; habitat abandonment
(temporary or permanent); and, in severe cases, panic, flight,
stampede, or stranding, potentially resulting in death (Southall et
al., 2007). A review of marine mammal responses to anthropogenic sound
was first conducted by Richardson and others in 1995. More recent
reviews (Nowacek et al., 2007; Ellison et al., 2012) address studies
conducted since 1995 and focuses on observations where the received
sound level of the exposed marine mammal(s) was known or could be
estimated. The following sub-sections provide examples of behavioral
responses that provide an idea of the variability in behavioral
responses that would be expected given the differential sensitivities
of marine mammal species to sound and the wide range of potential
acoustic sources to which a marine mammal may be exposed. Estimates of
the types of behavioral responses that could occur for a given sound
exposure should be determined from the literature that is available for
each species, or extrapolated from closely related species when no
information exists.
Flight Response--A flight response is a dramatic change in normal
movement to a directed and rapid movement away from the perceived
location of a sound source. Relatively little information on flight
responses of marine mammals to anthropogenic signals exist, although
observations of flight responses to the presence of predators have
occurred (Connor and Heithaus, 1996). Flight responses have been
speculated as being a component of marine mammal strandings associated
with sonar activities (Evans and England, 2001).
Response to Predator--Evidence suggests that at least some marine
mammals have the ability to acoustically identify potential predators.
For example, harbor seals that reside in the coastal waters off British
Columbia are frequently targeted by certain groups of killer whales,
but not others. The seals discriminate between the calls of threatening
and non-threatening killer whales (Deecke et al., 2002), a capability
that should increase survivorship while reducing the energy required
for attending to and responding to all killer whale calls. The
occurrence of masking or hearing impairment provides a means by which
marine mammals may be prevented from responding to the acoustic cues
produced by their predators. Whether or not this is a possibility
depends on the duration of the masking/hearing impairment and the
likelihood of encountering a predator during the time that predator
cues are impeded.
Diving--Changes in dive behavior can vary widely. They may consist
of increased or decreased dive times and surface intervals as well as
changes in the rates of ascent and descent during a dive. Variations in
dive behavior may reflect interruptions in biologically significant
activities (e.g., foraging) or they may be of little biological
significance. Variations in dive behavior may also expose an animal to
potentially harmful conditions (e.g., increasing the chance of ship-
strike) or may serve as an avoidance response that enhances
survivorship. The impact of a variation in diving resulting from an
acoustic exposure depends on what the animal is doing at the time of
the exposure and the type and magnitude of the response.
Nowacek et al. (2004) reported disruptions of dive behaviors in
foraging North Atlantic right whales when exposed to an alerting
stimulus, an action, they noted, that could lead to an increased
likelihood of ship strike. However, the whales did not respond to
playbacks of either right whale social sounds or vessel noise,
highlighting the importance of the sound characteristics in producing a
behavioral reaction. Conversely, Indo-Pacific humpback dolphins have
been observed to dive for longer periods of time in areas where vessels
were present and/or approaching (Ng and Leung, 2003). In both of these
studies, the influence of the sound exposure cannot be decoupled from
the physical presence of a surface vessel, thus complicating
interpretations of the relative contribution of each stimulus to the
response. Indeed, the presence of surface vessels, their approach, and
speed of approach, seemed to be significant factors in the response of
the Indo-Pacific humpback dolphins (Ng and Leung, 2003). Low frequency
signals of the Acoustic Thermometry of Ocean Climate (ATOC) sound
source were not found to affect dive times of humpback whales in
Hawaiian waters (Frankel and Clark, 2000) or to overtly affect elephant
seal dives (Costa et al., 2003). They did, however, produce subtle
effects that varied in direction and degree among the individual seals,
illustrating the equivocal nature of behavioral effects and consequent

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difficulty in defining and predicting them.
Due to past incidents of beaked whale strandings associated with
sonar operations, feedback paths are provided between avoidance and
diving and indirect tissue effects. This feedback accounts for the
hypothesis that variations in diving behavior and/or avoidance
responses can possibly result in nitrogen tissue supersaturation and
nitrogen off-gassing, possibly to the point of deleterious vascular
bubble formation (Jepson et al., 2003). Although hypothetical,
discussions surrounding this potential process are controversial.
Foraging--Disruption of feeding behavior can be difficult to
correlate with anthropogenic sound exposure, so it is usually inferred
by observed displacement from known foraging areas, the appearance of
secondary indicators (e.g., bubble nets or sediment plumes), or changes
in dive behavior. Noise from seismic surveys was not found to impact
the feeding behavior in western grey whales off the coast of Russia
(Yazvenko et al., 2007) and sperm whales engaged in foraging dives did
not abandon dives when exposed to distant signatures of seismic airguns
(Madsen et al., 2006). However, Miller et al. (2009) reported buzz
rates (a proxy for feeding) 19 percent lower during exposure to distant
signatures of seismic airguns. Balaenopterid whales exposed to moderate
low-frequency signals similar to the ATOC sound source demonstrated no
variation in foraging activity (Croll et al., 2001), whereas five out
of six North Atlantic right whales exposed to an acoustic alarm
interrupted their foraging dives (Nowacek et al., 2004). Although the
received sound pressure levels were similar in the latter two studies,
the frequency, duration, and temporal pattern of signal presentation
were different. These factors, as well as differences in species
sensitivity, are likely contributing factors to the differential
response. Blue whales exposed to simulated mid-frequency sonar in the
Southern California Bight were less likely to produce low frequency
calls usually associated with feeding behavior (Melc[oacute]n et al.,
2012). However, Melcon et al. (2012) were unable to determine if
suppression of low frequency calls reflected a change in their feeding
performance or abandonment of foraging behavior and indicated that
implications of the documented responses are unknown. Further, it is
not known whether the lower rates of calling actually indicated a
reduction in feeding behavior or social contact since the study used
data from remotely deployed, passive acoustic monitoring buoys. In
contrast, blue whales increased their likelihood of calling when ship
noise was present, and decreased their likelihood of calling in the
presence of explosive noise, although this result was not statistically
significant (Melc[oacute]n et al., 2012). Additionally, the likelihood
of an animal calling decreased with the increased received level of
mid-frequency sonar, beginning at a SPL of approximately 110-120 dB re
1 [mu]Pa (Melc[oacute]n et al., 2012). Results from the 2010-2011 field
season of an ongoing behavioral response study in Southern California
waters indicated that, in some cases and at low received levels, tagged
blue whales responded to mid-frequency sonar but that those responses
were mild and there was a quick return to their baseline activity
(Southall et al., 2011; Southall et al., 2012b). A determination of
whether foraging disruptions incur fitness consequences will require
information on or estimates of the energetic requirements of the
individuals and the relationship between prey availability, foraging
effort and success, and the life history stage of the animal. Goldbogen
et al., (2013) monitored behavioral responses of tagged blue whales
located in feeding areas when exposed simulated MFA sonar. Responses
varied depending on behavioral context, with deep feeding whales being
more significantly affected (i.e., generalized avoidance; cessation of
feeding; increased swimming speeds; or directed travel away from the
source) compared to surface feeding individuals that typically showed
no change in behavior. Non-feeding whales also seemed to be affected by
exposure. The authors indicate that disruption of feeding and
displacement could impact individual fitness and health. However, for
this to be true, we would have to assume that an individual whale could
not compensate for this lost feeding opportunity by either immediately
feeding at another location, by feeding shortly after cessation of
acoustic exposure, or by feeding at a later time. There is no
indication this is the case, particularly since unconsumed prey would
likely still be available in the environment in most cases following
the cessation of acoustic exposure.
Breathing--Variations in respiration naturally vary with different
behaviors and variations in respiration rate as a function of acoustic
exposure can be expected to co-occur with other behavioral reactions,
such as a flight response or an alteration in diving. However,
respiration rates in and of themselves may be representative of
annoyance or an acute stress response. Mean exhalation rates of gray
whales at rest and while diving were found to be unaffected by seismic
surveys conducted adjacent to the whale feeding grounds (Gailey et al.,
2007). Studies with captive harbor porpoises showed increased
respiration rates upon introduction of acoustic alarms (Kastelein et
al., 2001; Kastelein et al., 2006a) and emissions for underwater data
transmission (Kastelein et al., 2005). However, exposure of the same
acoustic alarm to a striped dolphin under the same conditions did not
elicit a response (Kastelein et al., 2006a), again highlighting the
importance in understanding species differences in the tolerance of
underwater noise when determining the potential for impacts resulting
from anthropogenic sound exposure.
Social Relationships--Social interactions between mammals can be
affected by noise via the disruption of communication signals or by the
displacement of individuals. Disruption of social relationships
therefore depends on the disruption of other behaviors (e.g., caused
avoidance, masking, etc.) and no specific overview is provided here.
However, social disruptions must be considered in context of the
relationships that are affected. Long-term disruptions of mother/calf
pairs or mating displays have the potential to affect the growth and
survival or reproductive effort/success of individuals, respectively.
Vocalizations (also see Masking Section)--Vocal changes in response
to anthropogenic noise can occur across the repertoire of sound
production modes used by marine mammals, such as whistling,
echolocation click production, calling, and singing. Changes may result
in response to a need to compete with an increase in background noise
or may reflect an increased vigilance or startle response. For example,
in the presence of low-frequency active sonar, humpback whales have
been observed to increase the length of their ''songs'' (Miller et al.,
2000; Fristrup et al., 2003), possibly due to the overlap in
frequencies between the whale song and the low-frequency active sonar.
A similar compensatory effect for the presence of low-frequency vessel
noise has been suggested for right whales; right whales have been
observed to shift the frequency content of their calls upward while
reducing the rate of calling in areas of increased anthropogenic noise
(Parks et al., 2007; Roland et al., 2012). Killer whales off the
northwestern coast of the U.S. have been observed to increase the
duration of primary calls once a threshold in

[[Page 9967]]

observing vessel density (e.g., whale watching) was reached, which has
been suggested as a response to increased masking noise produced by the
vessels (Foote et al., 2004; NOAA, 2014b). In contrast, both sperm and
pilot whales potentially ceased sound production during the Heard
Island feasibility test (Bowles et al., 1994), although it cannot be
absolutely determined whether the inability to acoustically detect the
animals was due to the cessation of sound production or the
displacement of animals from the area.
Avoidance--Avoidance is the displacement of an individual from an
area as a result of the presence of a sound. Richardson et al. (1995)
noted that avoidance reactions are the most obvious manifestations of
disturbance in marine mammals. It is qualitatively different from the
flight response, but also differs in the magnitude of the response
(i.e., directed movement, rate of travel, etc.). Oftentimes avoidance
is temporary, and animals return to the area once the noise has ceased.
Longer term displacement is possible, however, which can lead to
changes in abundance or distribution patterns of the species in the
affected region if they do not become acclimated to the presence of the
sound (Blackwell et al., 2004; Bejder et al., 2006; Teilmann et al.,
2006). Acute avoidance responses have been observed in captive
porpoises and pinnipeds exposed to a number of different sound sources
(Kastelein et al., 2001; Finneran et al., 2003; Kastelein et al.,
2006a; Kastelein et al., 2006b). Short-term avoidance of seismic
surveys, low frequency emissions, and acoustic deterrents have also
been noted in wild populations of odontocetes (Bowles et al., 1994;
Goold, 1996; 1998; Stone et al., 2000; Morton and Symonds, 2002) and to
some extent in mysticetes (Gailey et al., 2007), while longer term or
repetitive/chronic displacement for some dolphin groups and for
manatees has been suggested to be due to the presence of chronic vessel
noise (Haviland-Howell et al., 2007; Miksis-Olds et al., 2007).
Maybaum (1993) conducted sound playback experiments to assess the
effects of MFAS on humpback whales in Hawaiian waters. Specifically,
she exposed focal pods to sounds of a 3.3-kHz sonar pulse, a sonar
frequency sweep from 3.1 to 3.6 kHz, and a control (blank) tape while
monitoring behavior, movement, and underwater vocalizations. The two
types of sonar signals (which both contained mid- and low-frequency
components) differed in their effects on the humpback whales, but both
resulted in avoidance behavior. The whales responded to the pulse by
increasing their distance from the sound source and responded to the
frequency sweep by increasing their swimming speeds and track
linearity. In the Caribbean, sperm whales avoided exposure to mid-
frequency submarine sonar pulses, in the range of 1000 Hz to 10,000 Hz
(IWC 2005).
Kvadsheim et al. (2007) conducted a controlled exposure experiment
in which killer whales fitted with D-tags were exposed to mid-frequency
active sonar (Source A: A 1.0 second upsweep 209 dB @ 1-2 kHz every 10
seconds for 10 minutes; Source B: With a 1.0 second upsweep 197 dB @ 6-
7 kHz every 10 seconds for 10 minutes). When exposed to Source A, a
tagged whale and the group it was traveling with did not appear to
avoid the source. When exposed to Source B, the tagged whales along
with other whales that had been carousel feeding, ceased feeding during
the approach of the sonar and moved rapidly away from the source. When
exposed to Source B, Kvadsheim and his co-workers reported that a
tagged killer whale seemed to try to avoid further exposure to the
sound field by the following behaviors: Immediately swimming away
(horizontally) from the source of the sound; engaging in a series of
erratic and frequently deep dives that seemed to take it below the
sound field; or swimming away while engaged in a series of erratic and
frequently deep dives. Although the sample sizes in this study are too
small to support statistical analysis, the behavioral responses of the
killer whales were consistent with the results of other studies.
In 2007, the first in a series of behavioral response studies, a
collaboration by the Navy, NMFS, and other scientists showed one beaked
whale (Mesoplodon densirostris) responding to an MFAS playback. Tyack
et al. (2011) indicates that the playback began when the tagged beaked
whale was vocalizing at depth (at the deepest part of a typical feeding
dive), following a previous control with no sound exposure. The whale
appeared to stop clicking significantly earlier than usual, when
exposed to mid-frequency signals in the 130-140 dB (rms) received level
range. After a few more minutes of the playback, when the received
level reached a maximum of 140-150 dB, the whale ascended on the slow
side of normal ascent rates with a longer than normal ascent, at which
point the exposure was terminated. The results are from a single
experiment and a greater sample size is needed before robust and
definitive conclusions can be drawn.
Tyack et al. (2011) also indicates that Blainville's beaked whales
appear to be sensitive to noise at levels well below expected TTS (~160
dB re1[mu]Pa). This sensitivity is manifest by an adaptive movement
away from a sound source. This response was observed irrespective of
whether the signal transmitted was within the band width of MFAS, which
suggests that beaked whales may not respond to the specific sound
signatures. Instead, they may be sensitive to any pulsed sound from a
point source in this frequency range. The response to such stimuli
appears to involve maximizing the distance from the sound source.
Stimpert et al. (2014) tagged a Baird's beaked whale, which was
subsequently exposed to simulated MFAS. Received levels of sonar on the
tag increased to a maximum of 138 dB re 1[mu]Pa, which occurred during
the first exposure dive. Some sonar received levels could not be
measured due to flow noise and surface noise on the tag.
Results from a 2007-2008 study conducted near the Bahamas showed a
change in diving behavior of an adult Blainville's beaked whale to
playback of MFAS and predator sounds (Boyd et al., 2008; Southall et
al. 2009; Tyack et al., 2011). Reaction to mid-frequency sounds
included premature cessation of clicking and termination of a foraging
dive, and a slower ascent rate to the surface. Results from a similar
behavioral response study in southern California waters have been
presented for the 2010-2011 field season (Southall et al. 2011;
DeRuiter et al., 2013b). DeRuiter et al. (2013b) presented results from
two Cuvier's beaked whales that were tagged and exposed to simulated
MFAS during the 2010 and 2011 field seasons of the southern California
behavioral response study. The 2011 whale was also incidentally exposed
to MFAS from a distant naval exercise. Received levels from the MFAS
signals from the controlled and incidental exposures were calculated as
84-144 and 78-106 dB re 1 [mu]Pa root mean square (rms), respectively.
Both whales showed responses to the controlled exposures, ranging from
initial orientation changes to avoidance responses characterized by
energetic fluking and swimming away from the source. However, the
authors did not detect similar responses to incidental exposure to
distant naval sonar exercises at comparable received levels, indicating
that context of the exposures (e.g., source proximity, controlled
source ramp-up) may have been a significant factor. Specifically, this
result suggests that caution is needed when using marine mammal
response data collected from smaller, nearer sound sources to predict
at what

[[Page 9968]]

received levels animals may repond to larger sound sources that are
significantly farther away--as the distance of the source appears to be
an important contextual variable and animals may be less responsive to
sources at notably greater distances. Cuvier's beaked whale responses
suggested particular sensitivity to sound exposure as consistent with
results for Blainville's beaked whale. Similarly, beaked whales exposed
to sonar during British training exercises stopped foraging (DSTL,
2007), and preliminary results of controlled playback of sonar may
indicate feeding/foraging disruption of killer whales and sperm whales
(Miller et al., 2011).
In the 2007-2008 Bahamas study, playback sounds of a potential
predator--a killer whale--resulted in a similar but more pronounced
reaction, which included longer inter-dive intervals and a sustained
straight-line departure of more than 20 km from the area (Boyd et al.,
2008; Southall et al. 2009; Tyack et al., 2011). The authors noted,
however, that the magnified reaction to the predator sounds could
represent a cumulative effect of exposure to the two sound types since
killer whale playback began approximately 2 hours after mid-frequency
source playback. Pilot whales and killer whales off Norway also
exhibited horizontal avoidance of a transducer with outputs in the mid-
frequency range (signals in the 1-2 kHz and 6-7 kHz ranges) (Miller et
al., 2011). Additionally, separation of a calf from its group during
exposure to MFAS playback was observed on one occasion (Miller et al.,
2011; 2012). Miller et al. (2012) noted that this single observed
mother-calf separation was unusual for several reasons, including the
fact that the experiment was conducted in an unusually narrow fjord
roughly 1 km wide and that the sonar exposure was started unusually
close to the pod including the calf. Both of these factors could have
contributed to calf separation. In contrast, preliminary analyses
suggest that none of the pilot whales or false killer whales in the
Bahamas showed an avoidance response to controlled exposure playbacks
(Southall et al., 2009).
Through analysis of the behavioral response studies, a preliminary
overarching effect of greater sensitivity to all anthropogenic
exposures was seen in beaked whales compared to the other odontocetes
studied (Southall et al., 2009). Therefore, recent studies have focused
specifically on beaked whale responses to active sonar transmissions or
controlled exposure playback of simulated sonar on various military
ranges (Defence Science and Technology Laboratory, 2007; Claridge and
Durban, 2009; Moretti et al., 2009; McCarthy et al., 2011; Miller et
al., 2012; Southall et al., 2011, 2012a, 2012b, 2013, 2014; Tyack et
al., 2011). In the Bahamas, Blainville's beaked whales located on the
range will move off-range during sonar use and return only after the
sonar transmissions have stopped, sometimes taking several days to do
so (Claridge and Durban 2009; Moretti et al., 2009; McCarthy et al.,
2011; Tyack et al., 2011). Moretti et al. (2014) used recordings from
seafloor-mounted hydrophones at the Atlantic Undersea Test and
Evaluation Center (AUTEC) to analyze the probability of Blainsville's
beaked whale dives before, during, and after Navy sonar exercises.
Orientation--A shift in an animal's resting state or an attentional
change via an orienting response represent behaviors that would be
considered mild disruptions if occurring alone. As previously
mentioned, the responses may co-occur with other behaviors; for
instance, an animal may initially orient toward a sound source, and
then move away from it. Thus, any orienting response should be
considered in context of other reactions that may occur.

Behavioral Responses

Southall et al. (2007) reports the results of the efforts of a
panel of experts in acoustic research from behavioral, physiological,
and physical disciplines that convened and reviewed the available
literature on marine mammal hearing and physiological and behavioral
responses to human-made sound with the goal of proposing exposure
criteria for certain effects. This peer-reviewed compilation of
literature is very valuable, though Southall et al. (2007) note that
not all data are equal, some have poor statistical power, insufficient
controls, and/or limited information on received levels, background
noise, and other potentially important contextual variables--such data
were reviewed and sometimes used for qualitative illustration but were
not included in the quantitative analysis for the criteria
recommendations. All of the studies considered, however, contain an
estimate of the received sound level when the animal exhibited the
indicated response.
In the Southall et al. (2007) publication, for the purposes of
analyzing responses of marine mammals to anthropogenic sound and
developing criteria, the authors differentiate between single pulse
sounds, multiple pulse sounds, and non-pulse sounds. MFAS/HFAS sonar is
considered a non-pulse sound. Southall et al. (2007) summarize the
studies associated with low-frequency, mid-frequency, and high-
frequency cetacean and pinniped responses to non-pulse sounds, based
strictly on received level, in Appendix C of their article
(incorporated by reference and summarized in the three paragraphs
below).
The studies that address responses of low-frequency cetaceans to
non-pulse sounds include data gathered in the field and related to
several types of sound sources (of varying similarity to MFAS/HFAS)
including: Vessel noise, drilling and machinery playback, low-frequency
M-sequences (sine wave with multiple phase reversals) playback,
tactical low-frequency active sonar playback, drill ships, Acoustic
Thermometry of Ocean Climate (ATOC) source, and non-pulse playbacks.
These studies generally indicate no (or very limited) responses to
received levels in the 90 to 120 dB re: 1 [mu]Pa range and an
increasing likelihood of avoidance and other behavioral effects in the
120 to 160 dB range. As mentioned earlier, though, contextual variables
play a very important role in the reported responses and the severity
of effects are not linear when compared to received level. Also, few of
the laboratory or field datasets had common conditions, behavioral
contexts or sound sources, so it is not surprising that responses
differ.
The studies that address responses of mid-frequency cetaceans to
non-pulse sounds include data gathered both in the field and the
laboratory and related to several different sound sources (of varying
similarity to MFAS/HFAS) including: Pingers, drilling playbacks, ship
and ice-breaking noise, vessel noise, Acoustic Harassment Devices
(AHDs), Acoustic Deterrent Devices (ADDs), MFAS, and non-pulse bands
and tones. Southall et al. (2007) were unable to come to a clear
conclusion regarding the results of these studies. In some cases,
animals in the field showed significant responses to received levels
between 90 and 120 dB, while in other cases these responses were not
seen in the 120 to 150 dB range. The disparity in results was likely
due to contextual variation and the differences between the results in
the field and laboratory data (animals typically responded at lower
levels in the field).
The studies that address responses of high-frequency cetaceans to
non-pulse sounds include data gathered both in the field and the
laboratory and related to several different sound sources (of varying
similarity to MFAS/HFAS) including: Pingers, AHDs, and various
laboratory non-pulse sounds. All of these data were collected from
harbor

[[Page 9969]]

porpoises. Southall et al. (2007) concluded that the existing data
indicate that harbor porpoises are likely sensitive to a wide range of
anthropogenic sounds at low received levels (~ 90 to 120 dB), at least
for initial exposures. All recorded exposures above 140 dB induced
profound and sustained avoidance behavior in wild harbor porpoises
(Southall et al., 2007). Rapid habituation was noted in some but not
all studies. There is no data to indicate whether other high frequency
cetaceans are as sensitive to anthropogenic sound as harbor porpoises.
The studies that address the responses of pinnipeds in water to
non-impulsive sounds include data gathered both in the field and the
laboratory and related to several different sound sources (of varying
similarity to MFAS/HFAS) including: AHDs, ATOC, various non-pulse
sounds used in underwater data communication, underwater drilling, and
construction noise. Few studies exist with enough information to
include them in the analysis. The limited data suggested that exposures
to non-pulse sounds between 90 and 140 dB generally do not result in
strong behavioral responses in pinnipeds in water, but no data exist at
higher received levels.

Potential Effects of Behavioral Disturbance

The different ways that marine mammals respond to sound are
sometimes indicators of the ultimate effect that exposure to a given
stimulus will have on the well-being (survival, reproduction, etc.) of
an animal. There is limited marine mammal data quantitatively relating
the exposure of marine mammals to sound to effects on reproduction or
survival, though data exists for terrestrial species to which we can
draw comparisons for marine mammals.
Attention is the cognitive process of selectively concentrating on
one aspect of an animal's environment while ignoring other things
(Posner, 1994). Because animals (including humans) have limited
cognitive resources, there is a limit to how much sensory information
they can process at any time. The phenomenon called ``attentional
capture'' occurs when a stimulus (usually a stimulus that an animal is
not concentrating on or attending to) ``captures'' an animal's
attention. This shift in attention can occur consciously or
subconsciously (for example, when an animal hears sounds that it
associates with the approach of a predator) and the shift in attention
can be sudden (Dukas, 2002; van Rij, 2007). Once a stimulus has
captured an animal's attention, the animal can respond by ignoring the
stimulus, assuming a ``watch and wait'' posture, or treat the stimulus
as a disturbance and respond accordingly, which includes scanning for
the source of the stimulus or ``vigilance'' (Cowlishaw et al., 2004).
Vigilance is normally an adaptive behavior that helps animals
determine the presence or absence of predators, assess their distance
from conspecifics, or to attend cues from prey (Bednekoff and Lima,
1998; Treves, 2000). Despite those benefits, however, vigilance has a
cost of time; when animals focus their attention on specific
environmental cues, they are not attending to other activities such as
foraging. These costs have been documented best in foraging animals,
where vigilance has been shown to substantially reduce feeding rates
(Saino, 1994; Beauchamp and Livoreil, 1997; Fritz et al., 2002).
Animals will spend more time being vigilant, which may translate to
less time foraging or resting, when disturbance stimuli approach them
more directly, remain at closer distances, have a greater group size
(for example, multiple surface vessels), or when they co-occur with
times that an animal perceives increased risk (for example, when they
are giving birth or accompanied by a calf). Most of the published
literature, however, suggests that direct approaches will increase the
amount of time animals will dedicate to being vigilant. For example,
bighorn sheep and Dall's sheep dedicated more time being vigilant, and
less time resting or foraging, when aircraft made direct approaches
over them (Frid, 2001; Stockwell et al., 1991).
Several authors have established that long-term and intense
disturbance stimuli can cause population declines by reducing the body
condition of individuals that have been disturbed, followed by reduced
reproductive success, reduced survival, or both (Daan et al., 1996;
Madsen, 1994; White, 1983). For example, Madsen (1994) reported that
pink-footed geese in undisturbed habitat gained body mass and had about
a 46-percent reproductive success rate compared with geese in disturbed
habitat (being consistently scared off the fields on which they were
foraging) which did not gain mass and had a 17-percent reproductive
success rate. Similar reductions in reproductive success have been
reported for mule deer disturbed by all-terrain vehicles (Yarmoloy et
al., 1988), caribou disturbed by seismic exploration blasts (Bradshaw
et al., 1998), caribou disturbed by low-elevation military jet-fights
(Luick et al., 1996), and caribou disturbed by low-elevation jet
flights (Harrington and Veitch, 1992). Similarly, a study of elk that
were disturbed experimentally by pedestrians concluded that the ratio
of young to mothers was inversely related to disturbance rate (Phillips
and Alldredge, 2000).
The primary mechanism by which increased vigilance and disturbance
appear to affect the fitness of individual animals is by disrupting an
animal's time budget and, as a result, reducing the time they might
spend foraging and resting (which increases an animal's activity rate
and energy demand). For example, a study of grizzly bears reported that
bears disturbed by hikers reduced their energy intake by an average of
12 kcal/minute (50.2 x 10\3\kJ/minute), and spent energy fleeing or
acting aggressively toward hikers (White et al. 1999). Alternately,
Ridgway et al. (2006) reported that increased vigilance in bottlenose
dolphins exposed to sound over a 5-day period did not cause any sleep
deprivation or stress effects such as changes in cortisol or
epinephrine levels.
Lusseau and Bejder (2007) present data from three long-term studies
illustrating the connections between disturbance from whale-watching
boats and population-level effects in cetaceans. In Sharks Bay
Australia, the abundance of bottlenose dolphins was compared within
adjacent control and tourism sites over three consecutive 4.5-year
periods of increasing tourism levels. Between the second and third time
periods, in which tourism doubled, dolphin abundance decreased by 15
percent in the tourism area and did not change significantly in the
control area. In Fiordland, New Zealand, two populations (Milford and
Doubtful Sounds) of bottlenose dolphins with tourism levels that
differed by a factor of seven were observed and significant increases
in travelling time and decreases in resting time were documented for
both. Consistent short-term avoidance strategies were observed in
response to tour boats until a threshold of disturbance was reached
(average 68 minutes between interactions), after which the response
switched to a longer term habitat displacement strategy. For one
population tourism only occurred in a part of the home range, however,
tourism occurred throughout the home range of the Doubtful Sound
population and once boat traffic increased beyond the 68-minute
threshold (resulting in abandonment of their home range/preferred
habitat), reproductive success drastically decreased (increased

[[Page 9970]]

stillbirths) and abundance decreased significantly (from 67 to 56
individuals in short period). Last, in a study of northern resident
killer whales off Vancouver Island, exposure to boat traffic was shown
to reduce foraging opportunities and increase traveling time. A simple
bioenergetics model was applied to show that the reduced foraging
opportunities equated to a decreased energy intake of 18 percent, while
the increased traveling incurred an increased energy output of 3-4
percent, which suggests that a management action based on avoiding
interference with foraging might be particularly effective.
On a related note, many animals perform vital functions, such as
feeding, resting, traveling, and socializing, on a diel cycle (24-hour
cycle). Substantive behavioral reactions to noise exposure (such as
disruption of critical life functions, displacement, or avoidance of
important habitat) are more likely to be significant if they last more
than one diel cycle or recur on subsequent days (Southall et al.,
2007). Consequently, a behavioral response lasting less than 1 day and
not recurring on subsequent days is not considered particularly severe
unless it could directly affect reproduction or survival (Southall et
al., 2007). Note that there is a difference between multiple-day
substantive behavioral reactions and multiple-day anthropogenic
activities. For example, just because an at-sea exercises last for
multiple days does not necessarily mean that individual animals are
either exposed to those exercises for multiple days or, further,
exposed in a manner resulting in a sustained multiple day substantive
behavioral responses.
In order to understand how the effects of activities may or may not
impact stocks and populations of marine mammals, it is necessary to
understand not only what the likely disturbances are going to be, but
how those disturbances may affect the reproductive success and
survivorship of individuals, and then how those impacts to individuals
translate to population changes. Following on the earlier work of a
committee of the U.S. National Research Council (NRC, 2005), New et al.
(2014), in an effort termed the Potential Consequences of Disturbance
(PCoD), outline an updated conceptual model of the relationships
linking disturbance to changes in behavior and physiology, health,
vital rates, and population dynamics (below). As depicted, behavioral
and physiological changes can either have direct (acute) effects on
vital rates, such as when changes in habitat use or increased stress
levels raise the probability of mother-calf separation or predation, or
they can have indirect and long-term (chronic) effects on vital rates,
such as when changes in time/energy budgets or increased disease
susceptibility affect health, which then affects vital rates (New et
al., 2014). In addition to outlining this general framework and
compiling the relevant literature that supports it, New et al. (2014)
have chosen four example species for which extensive long-term
monitoring data exist (southern elephant seals, North Atlantic right
whales, Ziphidae beaked whales, and bottlenose dolphins) and developed
state-space energetic models that can be used to effectively forecast
longer-term, population-level impacts from behavioral changes. While
these are very specific models with very specific data requirements
that cannot yet be applied broadly to project-specific risk
assessments, they are a critical first step.

Stranding and Mortality

When a live or dead marine mammal swims or floats onto shore and
becomes ``beached'' or incapable of returning to sea, the event is
termed a ``stranding'' (Geraci et al., 1999; Perrin and Geraci, 2002;
Geraci and Lounsbury, 2005; NMFS, 2007). The legal definition for a
stranding within the U.S. can be found in section 410 of the MMPA (16
U.S.C. 1421h).
Marine mammals are known to strand for a variety of reasons, such
as infectious agents, biotoxicosis, starvation, fishery interaction,
ship strike, unusual oceanographic or weather events, sound exposure,
or combinations of these stressors sustained concurrently or in series.
However, the cause or causes of most strandings are unknown (Geraci et
al., 1976; Eaton, 1979, Odell et al., 1980; Best, 1982). Numerous
studies suggest that the physiology, behavior, habitat relationships,
age, or condition of cetaceans may cause them to strand or might pre-
dispose them to strand when exposed to another phenomenon. These
suggestions are consistent with the conclusions of numerous other
studies that have demonstrated that combinations of dissimilar
stressors commonly combine to kill an animal or dramatically reduce its
fitness, even though one exposure without the other does not produce
the same result (Chroussos, 2000; Creel, 2005; DeVries et al., 2003;
Fair and Becker, 2000; Foley et al., 2001; Moberg, 2000; Relyea, 2005a;
2005b, Romero, 2004; Sih et al., 2004). For reference, between 2001 and
2009, there was an annual average of 1,400 cetacean strandings and
4,300 pinniped strandings along the coasts of the continental U.S. and
Alaska (NMFS, 2011).
Several sources have published lists of mass stranding events of
cetaceans in an attempt to identify relationships between those
stranding events and military sonar (Hildebrand, 2004; IWC, 2005;
Taylor et al., 2004). For example, based on a review of stranding
records between 1960 and 1995, the International Whaling Commission
(2005) identified ten mass stranding events of Cuvier's beaked whales
had been reported and one mass stranding of four Baird's beaked whale.
The IWC concluded that, out of eight stranding events reported from the
mid-1980s to the summer of 2003, seven had been coincident with the use
of tactical mid-frequency sonar, one of those seven had been associated
with the use of tactical low-frequency sonar, and the remaining
stranding event had been associated with the use of seismic airguns.
Most of the stranding events reviewed by the International Whaling
Commission involved beaked whales. A mass stranding of Cuvier's beaked
whales in the eastern Mediterranean Sea occurred in 1996 (Frantzis,
1998) and mass stranding events involving Gervais' beaked whales,
Blainville's beaked whales, and Cuvier's beaked whales occurred off the
coast of the Canary Islands in the late 1980s (Simmonds and Lopez-
Jurado, 1991). The stranding events that occurred in the Canary Islands
and Kyparissiakos Gulf in the late 1990s and the Bahamas in 2000 have
been the most intensively-studied mass stranding events and have been
associated with naval maneuvers involving the use of tactical sonar.
Between 1960 and 2006, 48 strandings (68 percent) involved beaked
whales, three (4 percent) involved dolphins, and 14 (20 percent)
involved whale species. Cuvier's beaked whales were involved in the
greatest number of these events (48 or 68 percent), followed by sperm
whales (seven or 10 percent), and Blainville's and Gervais' beaked
whales (four each or 6 percent). Naval activities (not just activities
conducted by the U.S. Navy) that might have involved active sonar are
reported to have coincided with nine or 10 (13 to 14 percent) of those
stranding events. Between the mid-1980s and 2003 (the period reported
by the International Whaling Commission), NMFS identified reports of 44
mass cetacean stranding events of which at least seven were coincident
with naval exercises that were using MFAS.

[[Page 9971]]

Strandings Associated With Impulsive Sound

Silver Strand--During a Navy training event on March 4, 2011 at the
Silver Strand Training Complex in San Diego, California, three or
possibly four dolphins were killed in an explosion. During an
underwater detonation training event, a pod of 100 to 150 long-beaked
common dolphins were observed moving towards the 700-yd (640.1-m)
exclusion zone around the explosive charge, monitored by personnel in a
safety boat and participants in a dive boat. Approximately 5 minutes
remained on a time-delay fuse connected to a single 8.76 lb (3.97 kg)
explosive charge (C-4 and detonation cord). Although the dive boat was
placed between the pod and the explosive in an effort to guide the
dolphins away from the area, that effort was unsuccessful and three
long-beaked common dolphins near the explosion died. In addition to the
three dolphins found dead on March 4, the remains of a fourth dolphin
were discovered on March 7, 2011 near Ocean Beach, California (3 days
later and approximately 11.8 mi. [19 km] from Silver Strand where the
training event occurred), which might also have been related to this
event. Association of the fourth stranding with the training event is
uncertain because dolphins strand on a regular basis in the San Diego
area. Details such as the dolphins' depth and distance from the
explosive at the time of the detonation could not be estimated from the
250 yd (228.6 m) standoff point of the observers in the dive boat or
the safety boat.
These dolphin mortalities are the only known occurrence of a U.S.
Navy training or testing event involving impulsive energy (underwater
detonation) that caused mortality or injury to a marine mammal (of
note, the time-delay firing underwater explosive training activity
implicated in the March 4 incident is not proposed for the training
activities in the GOA Study Area). Despite this being a rare
occurrence, the Navy has reviewed training requirements, safety
procedures, and possible mitigation measures and implemented changes to
reduce the potential for this to occur in the future. Discussions of
procedures associated with underwater explosives training and other
training events are presented in the Proposed Mitigation section.
Kyle of Durness, Scotland--On July 22, 2011 a mass stranding event
involving long-finned pilot whales occurred at Kyle of Durness,
Scotland. An investigation by Brownlow et al. (2015) considered
unexploded ordnance detonation activities at a Ministry of Defense
bombing range, conducted by the Royal Navy prior to and during the
strandings, as a plausible contributing factor in the mass stranding
event. While Brownlow et al. (2015) concluded that the serial
detonations of underwater ordnance were an influential factor in the
mass stranding event (along with presence of a potentially compromised
animal and navigational error in a topographically complex region) they
also suggest that mitigation measures--which included observations from
a zodiac only and by personnel not experienced in marine mammal
observation, among other deficiencies--were likely insufficient to
assess if cetaceans were in the vicinity of the detonations. The
authors also cite information from the Ministry of Defense indicating
``an extraordinarily high level of activity'' (i.e., frequency and
intensity of underwater explosions) on the range in the days leading up
to the stranding.

Strandings Associated With MFAS

Over the past 16 years, there have been five stranding events
coincident with military mid-frequency sonar use in which exposure to
sonar is believed to have been a contributing factor: Greece (1996);
the Bahamas (2000); Madeira (2000); Canary Islands (2002); and Spain
(2006). Additionally, in 2004, during the Rim of the Pacific (RIMPAC)
exercises, between 150 and 200 usually pelagic melon-headed whales
occupied the shallow waters of Hanalei Bay, Kauai, Hawaii for over 28
hours. NMFS determined that MFAS was a plausible, if not likely,
contributing factor in what may have been a confluence of events that
led to the stranding. A number of other stranding events coincident
with the operation of mid-frequency sonar, including the death of
beaked whales or other species (minke whales, dwarf sperm whales, pilot
whales), have been reported; however, the majority have not been
investigated to the degree necessary to determine the cause of the
stranding and only one of these stranding events, the Bahamas (2000),
was associated with exercises conducted by the U.S. Navy. Most
recently, the Independent Scientific Review Panel investigating
potential contributing factors to a 2008 mass stranding of melon-headed
whales in Antsohihy, Madagascar released its final report suggesting
that the stranding was likely initially triggered by an industry
seismic survey. This report suggests that the operation of a commercial
high-powered 12 kHz multi-beam echosounder during an industry seismic
survey was a plausible and likely initial trigger that caused a large
group of melon-headed whales to leave their typical habitat and then
ultimately strand as a result of secondary factors such as
malnourishment and dehydration. The report indicates that the risk of
this particular convergence of factors and ultimate outcome is likely
very low, but recommends that the potential be considered in
environmental planning. Because of the association between tactical
mid-frequency active sonar use and a small number of marine mammal
strandings, the Navy and NMFS have been considering and addressing the
potential for strandings in association with Navy activities for years.
In addition to a suite of mitigation intended to more broadly minimize
impacts to marine mammals, the Navy and NMFS have a detailed Stranding
Response Plan that outlines reporting, communication, and response
protocols intended both to minimize the impacts of, and enhance the
analysis of, any potential stranding in areas where the Navy operates.
Greece (1996)--Twelve Cuvier's beaked whales stranded atypically
(in both time and space) along a 38.2-km strand of the Kyparissiakos
Gulf coast on May 12 and 13, 1996 (Frantzis, 1998). From May 11 through
May 15, the North Atlantic Treaty Organization (NATO) research vessel
Alliance was conducting sonar tests with signals of 600 Hz and 3 kHz
and source levels of 228 and 226 dB re: 1[mu]Pa, respectively (D'Amico
and Verboom, 1998; D'Spain et al., 2006). The timing and location of
the testing encompassed the time and location of the strandings
(Frantzis, 1998).
Necropsies of eight of the animals were performed but were limited
to basic external examination and sampling of stomach contents, blood,
and skin. No ears or organs were collected, and no histological samples
were preserved. No apparent abnormalities or wounds were found.
Examination of photos of the animals, taken soon after their death,
revealed that the eyes of at least four of the individuals were
bleeding. Photos were taken soon after their death (Frantzis, 2004).
Stomach contents contained the flesh of cephalopods, indicating that
feeding had recently taken place (Frantzis, 1998).
All available information regarding the conditions associated with
this stranding event were compiled, and many potential causes were
examined including major pollution events, prominent tectonic activity,
unusual physical or meteorological events,

[[Page 9972]]

magnetic anomalies, epizootics, and conventional military activities
(International Council for the Exploration of the Sea, 2005a). However,
none of these potential causes coincided in time or space with the mass
stranding, or could explain its characteristics (International Council
for the Exploration of the Sea, 2005a). The robust condition of the
animals, plus the recent stomach contents, is inconsistent with
pathogenic causes. In addition, environmental causes can be ruled out
as there were no unusual environmental circumstances or events before
or during this time period and within the general proximity (Frantzis,
2004).
Because of the rarity of this mass stranding of Cuvier's beaked
whales in the Kyparissiakos Gulf (first one in history), the
probability for the two events (the military exercises and the
strandings) to coincide in time and location, while being independent
of each other, was thought to be extremely low (Frantzis, 1998).
However, because full necropsies had not been conducted, and no
abnormalities were noted, the cause of the strandings could not be
precisely determined (Cox et al., 2006). A Bioacoustics Panel convened
by NATO concluded that the evidence available did not allow them to
accept or reject sonar exposures as a causal agent in these stranding
events. The analysis of this stranding event provided support for, but
no clear evidence for, the cause-and-effect relationship of tactical
sonar training activities and beaked whale strandings (Cox et al.,
2006).
Bahamas (2000)--NMFS and the Navy prepared a joint report
addressing the multi-species stranding in the Bahamas in 2000, which
took place within 24 hours of U.S. Navy ships using MFAS as they passed
through the Northeast and Northwest Providence Channels on March 15-16,
2000. The ships, which operated both AN/SQS-53C and AN/SQS-56, moved
through the channel while emitting sonar pings approximately every 24
seconds. Of the 17 cetaceans that stranded over a 36-hr period
(Cuvier's beaked whales, Blainville's beaked whales, minke whales, and
a spotted dolphin), seven animals died on the beach (five Cuvier's
beaked whales, one Blainville's beaked whale, and the spotted dolphin),
while the other 10 were returned to the water alive (though their
ultimate fate is unknown). As discussed in the Bahamas report (DOC/DON,
2001), there is no likely association between the minke whale and
spotted dolphin strandings and the operation of MFAS.
Necropsies were performed on five of the stranded beaked whales.
All five necropsied beaked whales were in good body condition, showing
no signs of infection, disease, ship strike, blunt trauma, or fishery
related injuries, and three still had food remains in their stomachs.
Auditory structural damage was discovered in four of the whales,
specifically bloody effusions or hemorrhaging around the ears.
Bilateral intracochlear and unilateral temporal region subarachnoid
hemorrhage, with blood clots in the lateral ventricles, were found in
two of the whales. Three of the whales had small hemorrhages in their
acoustic fats (located along the jaw and in the melon).
A comprehensive investigation was conducted and all possible causes
of the stranding event were considered, whether they seemed likely at
the outset or not. Based on the way in which the strandings coincided
with ongoing naval activity involving tactical MFAS use, in terms of
both time and geography, the nature of the physiological effects
experienced by the dead animals, and the absence of any other acoustic
sources, the investigation team concluded that MFAS aboard U.S. Navy
ships that were in use during the active sonar exercise in question
were the most plausible source of this acoustic or impulse trauma to
beaked whales. This sound source was active in a complex environment
that included the presence of a surface duct, unusual and steep
bathymetry, a constricted channel with limited egress, intensive use of
multiple, active sonar units over an extended period of time, and the
presence of beaked whales that appear to be sensitive to the
frequencies produced by these active sonars. The investigation team
concluded that the cause of this stranding event was the confluence of
the Navy MFAS and these contributory factors working together, and
further recommended that the Navy avoid operating MFAS in situations
where these five factors would be likely to occur. This report does not
conclude that all five of these factors must be present for a stranding
to occur, nor that beaked whales are the only species that could
potentially be affected by the confluence of the other factors. Based
on this, NMFS believes that the operation of MFAS in situations where
surface ducts exist, or in marine environments defined by steep
bathymetry and/or constricted channels may increase the likelihood of
producing a sound field with the potential to cause cetaceans
(especially beaked whales) to strand, and therefore, suggests the need
for increased vigilance while operating MFAS in these areas, especially
when beaked whales (or potentially other deep divers) are likely
present.
Madeira, Spain (2000)--From May 10-14, 2000, three Cuvier's beaked
whales were found atypically stranded on two islands in the Madeira
archipelago, Portugal (Cox et al., 2006). A fourth animal was reported
floating in the Madeiran waters by fisherman but did not come ashore
(Woods Hole Oceanographic Institution, 2005). Joint NATO amphibious
training peacekeeping exercises involving participants from 17
countries 80 warships, took place in Portugal during May 2-15, 2000.
The bodies of the three stranded whales were examined post mortem
(Woods Hole Oceanographic Institution, 2005), though only one of the
stranded whales was fresh enough (24 hours after stranding) to be
necropsied (Cox et al., 2006). Results from the necropsy revealed
evidence of hemorrhage and congestion in the right lung and both
kidneys (Cox et al., 2006). There was also evidence of intercochlear
and intracranial hemorrhage similar to that which was observed in the
whales that stranded in the Bahamas event (Cox et al., 2006). There
were no signs of blunt trauma, and no major fractures (Woods Hole
Oceanographic Institution, 2005). The cranial sinuses and airways were
found to be clear with little or no fluid deposition, which may
indicate good preservation of tissues (Woods Hole Oceanographic
Institution, 2005).
Several observations on the Madeira stranded beaked whales, such as
the pattern of injury to the auditory system, are the same as those
observed in the Bahamas strandings. Blood in and around the eyes,
kidney lesions, pleural hemorrhages, and congestion in the lungs are
particularly consistent with the pathologies from the whales stranded
in the Bahamas, and are consistent with stress and pressure related
trauma. The similarities in pathology and stranding patterns between
these two events suggest that a similar pressure event may have
precipitated or contributed to the strandings at both sites (Woods Hole
Oceanographic Institution, 2005).
Even though no definitive causal link can be made between the
stranding event and naval exercises, certain conditions may have
existed in the exercise area that, in their aggregate, may have
contributed to the marine mammal strandings (Freitas, 2004): Exercises
were conducted in areas of at least 547 fathoms (1,000 m) depth near a
shoreline where there is a rapid change in bathymetry on the order of
547 to 3,281 fathoms (1,000 to 6,000 m) occurring across a relatively
short

[[Page 9973]]

horizontal distance (Freitas, 2004); multiple ships were operating
around Madeira, though it is not known if MFAS was used, and the
specifics of the sound sources used are unknown (Cox et al., 2006,
Freitas, 2004); and exercises took place in an area surrounded by
landmasses separated by less than 35 nm (65 km) and at least 10 nm (19
km) in length, or in an embayment. Exercises involving multiple ships
employing MFAS near land may produce sound directed towards a channel
or embayment that may cut off the lines of egress for marine mammals
(Freitas, 2004).
Canary Islands, Spain (2002)--The southeastern area within the
Canary Islands is well known for aggregations of beaked whales due to
its ocean depths of greater than 547 fathoms (1,000 m) within a few
hundred meters of the coastline (Fernandez et al., 2005). On September
24, 2002, 14 beaked whales were found stranded on Fuerteventura and
Lanzarote Islands in the Canary Islands (International Council for
Exploration of the Sea, 2005a). Seven whales died, while the remaining
seven live whales were returned to deeper waters (Fernandez et al.,
2005). Four beaked whales were found stranded dead over the next three
days either on the coast or floating offshore. These strandings
occurred within near proximity of an international naval exercise that
utilized MFAS and involved numerous surface warships and several
submarines. Strandings began about 4 hours after the onset of MFAS
activity (International Council for Exploration of the Sea, 2005a;
Fernandez et al., 2005).
Eight Cuvier's beaked whales, one Blainville's beaked whale, and
one Gervais' beaked whale were necropsied, six of them within 12 hours
of stranding (Fernandez et al., 2005). No pathogenic bacteria were
isolated from the carcasses (Jepson et al., 2003). The animals
displayed severe vascular congestion and hemorrhage especially around
the tissues in the jaw, ears, brain, and kidneys, displaying marked
disseminated microvascular hemorrhages associated with widespread fat
emboli (Jepson et al., 2003; International Council for Exploration of
the Sea, 2005a). Several organs contained intravascular bubbles,
although definitive evidence of gas embolism in vivo is difficult to
determine after death (Jepson et al., 2003). The livers of the
necropsied animals were the most consistently affected organ, which
contained macroscopic gas-filled cavities and had variable degrees of
fibrotic encapsulation. In some animals, cavitary lesions had
extensively replaced the normal tissue (Jepson et al., 2003). Stomachs
contained a large amount of fresh and undigested contents, suggesting a
rapid onset of disease and death (Fernandez et al., 2005). Head and
neck lymph nodes were enlarged and congested, and parasites were found
in the kidneys of all animals (Fernandez et al., 2005).
The association of NATO MFAS use close in space and time to the
beaked whale strandings, and the similarity between this stranding
event and previous beaked whale mass strandings coincident with sonar
use, suggests that a similar scenario and causative mechanism of
stranding may be shared between the events. Beaked whales stranded in
this event demonstrated brain and auditory system injuries,
hemorrhages, and congestion in multiple organs, similar to the
pathological findings of the Bahamas and Madeira stranding events. In
addition, the necropsy results of Canary Islands stranding event lead
to the hypothesis that the presence of disseminated and widespread gas
bubbles and fat emboli were indicative of nitrogen bubble formation,
similar to what might be expected in decompression sickness (Jepson et
al., 2003; Fern[aacute]ndez et al., 2005).
Hanalei Bay (2004)--On July 3 and 4, 2004, approximately 150 to 200
melon-headed whales occupied the shallow waters of the Hanalei Bay,
Kaua'i, Hawaii for over 28 hrs. Attendees of a canoe blessing observed
the animals entering the Bay in a single wave formation at 7 a.m. on
July 3, 2004. The animals were observed moving back into the shore from
the mouth of the Bay at 9 a.m. The usually pelagic animals milled in
the shallow bay and were returned to deeper water with human assistance
beginning at 9:30 a.m. on July 4, 2004, and were out of sight by 10:30
a.m.
Only one animal, a calf, was known to have died following this
event. The animal was noted alive and alone in the Bay on the afternoon
of July 4, 2004, and was found dead in the Bay the morning of July 5,
2004. A full necropsy, magnetic resonance imaging, and computerized
tomography examination were performed on the calf to determine the
manner and cause of death. The combination of imaging, necropsy and
histological analyses found no evidence of infectious, internal
traumatic, congenital, or toxic factors. Cause of death could not be
definitively determined, but it is likely that maternal separation,
poor nutritional condition, and dehydration contributed to the final
demise of the animal. Although it is not known when the calf was
separated from its mother, the animals' movement into the Bay and
subsequent milling and re-grouping may have contributed to the
separation or lack of nursing, especially if the maternal bond was weak
or this was an inexperienced mother with her first calf.
Environmental factors, abiotic and biotic, were analyzed for any
anomalous occurrences that would have contributed to the animals
entering and remaining in Hanalei Bay. The Bay's bathymetry is similar
to many other sites within the Hawaiian Island chain and dissimilar to
sites that have been associated with mass strandings in other parts of
the U.S. The weather conditions appeared to be normal for that time of
year with no fronts or other significant features noted. There was no
evidence of unusual distribution, occurrence of predator or prey
species, or unusual harmful algal blooms, although Mobley et al. (2007)
suggested that the full moon cycle that occurred at that time may have
influenced a run of squid into the Bay. Weather patterns and bathymetry
that have been associated with mass strandings elsewhere were not found
to occur in this instance.
The Hanalei event was spatially and temporally correlated with
RIMPAC. Official sonar training and tracking exercises in the Pacific
Missile Range Facility (PMRF) warning area did not commence until
approximately 8 a.m. on July 3 and were thus ruled out as a possible
trigger for the initial movement into the Bay. However, six naval
surface vessels transiting to the operational area on July 2
intermittently transmitted active sonar (for approximately 9 hours
total from 1:15 p.m. to 12:30 a.m.) as they approached from the south.
The potential for these transmissions to have triggered the whales'
movement into Hanalei Bay was investigated. Analyses with the
information available indicated that animals to the south and east of
Kaua'i could have detected active sonar transmissions on July 2, and
reached Hanalei Bay on or before 7 a.m. on July 3. However, data
limitations regarding the position of the whales prior to their arrival
in the Bay, the magnitude of sonar exposure, behavioral responses of
melon-headed whales to acoustic stimuli, and other possible relevant
factors preclude a conclusive finding regarding the role of sonar in
triggering this event. Propagation modeling suggests that transmissions
from sonar use during the July 3 exercise in the PMRF warning area may
have been detectable at the mouth of the Bay. If the animals responded
negatively to these signals, it may have contributed to their continued
presence in the Bay. The U.S.

[[Page 9974]]

Navy ceased all active sonar transmissions during exercises in this
range on the afternoon of July 3. Subsequent to the cessation of sonar
use, the animals were herded out of the Bay.
While causation of this stranding event may never be unequivocally
determined, NMFS consider the active sonar transmissions of July 2-3,
2004, a plausible, if not likely, contributing factor in what may have
been a confluence of events. This conclusion is based on the following:
(1) The evidently anomalous nature of the stranding; (2) its close
spatiotemporal correlation with wide-scale, sustained use of sonar
systems previously associated with stranding of deep-diving marine
mammals; (3) the directed movement of two groups of transmitting
vessels toward the southeast and southwest coast of Kauai; (4) the
results of acoustic propagation modeling and an analysis of possible
animal transit times to the Bay; and (5) the absence of any other
compelling causative explanation. The initiation and persistence of
this event may have resulted from an interaction of biological and
physical factors. The biological factors may have included the presence
of an apparently uncommon, deep-diving cetacean species (and possibly
an offshore, non-resident group), social interactions among the animals
before or after they entered the Bay, and/or unknown predator or prey
conditions. The physical factors may have included the presence of
nearby deep water, multiple vessels transiting in a directed manner
while transmitting active sonar over a sustained period, the presence
of surface sound ducting conditions, and/or intermittent and random
human interactions while the animals were in the Bay.
A separate event involving melon-headed whales and rough-toothed
dolphins took place over the same period of time in the Northern
Mariana Islands (Jefferson et al., 2006), which is several thousand
miles from Hawaii. Some 500 to 700 melon-headed whales came into
Sasanhaya Bay on July 4, 2004, near the island of Rota and then left of
their own accord after 5.5 hours; no known active sonar transmissions
occurred in the vicinity of that event. The Rota incident led to
scientific debate regarding what, if any, relationship the event had to
the simultaneous events in Hawaii and whether they might be related by
some common factor (e.g., there was a full moon on July 2, 2004, as
well as during other melon-headed whale strandings and nearshore
aggregations (Brownell et al., 2009; Lignon et al., 2007; Mobley et
al., 2007). Brownell et al. (2009) compared the two incidents, along
with one other stranding incident at Nuka Hiva in French Polynesia and
normal resting behaviors observed at Palmyra Island, in regard to
physical features in the areas, melon-headed whale behavior, and lunar
cycles. Brownell et al., (2009) concluded that the rapid entry of the
whales into Hanalei Bay, their movement into very shallow water far
from the 100-m contour, their milling behavior (typical pre-stranding
behavior), and their reluctance to leave the bay constituted an unusual
event that was not similar to the events that occurred at Rota (but was
similar to the events at Palmyra), which appear to be similar to
observations of melon-headed whales resting normally at Palmyra Island.
Additionally, there was no correlation between lunar cycle and the
types of behaviors observed in the Brownell et al. (2009) examples.
Spain (2006)--The Spanish Cetacean Society reported an atypical
mass stranding of four beaked whales that occurred January 26, 2006, on
the southeast coast of Spain, near Mojacar (Gulf of Vera) in the
Western Mediterranean Sea. According to the report, two of the whales
were discovered the evening of January 26 and were found to be still
alive. Two other whales were discovered during the day on January 27,
but had already died. The first three animals were located near the
town of Mojacar and the fourth animal was found dead, a few kilometers
north of the first three animals. From January 25-26, 2006, Standing
NATO Response Force Maritime Group Two (five of seven ships including
one U.S. ship under NATO Operational Control) had conducted active
sonar training against a Spanish submarine within 50 nm (93 km) of the
stranding site.
Veterinary pathologists necropsied the two male and two female
Cuvier's beaked whales. According to the pathologists, the most likely
primary cause of this type of beaked whale mass stranding event was
anthropogenic acoustic activities, most probably anti-submarine MFAS
used during the military naval exercises. However, no positive acoustic
link was established as a direct cause of the stranding. Even though no
causal link can be made between the stranding event and naval
exercises, certain conditions may have existed in the exercise area
that, in their aggregate, may have contributed to the marine mammal
strandings (Freitas, 2004): Exercises were conducted in areas of at
least 547 fathoms (1,000 m) depth near a shoreline where there is a
rapid change in bathymetry on the order of 547 to 3,281 fathoms (1,000
to 6,000 m) occurring across a relatively short horizontal distance
(Freitas, 2004); multiple ships (in this instance, five) were operating
MFAS in the same area over extended periods of time (in this case, 20
hours) in close proximity; and exercises took place in an area
surrounded by landmasses, or in an embayment. Exercises involving
multiple ships employing MFAS near land may have produced sound
directed towards a channel or embayment that may have cut off the lines
of egress for the affected marine mammals (Freitas, 2004).

Association Between Mass Stranding Events and Exposure to MFAS

Several authors have noted similarities between some of these
stranding incidents: They occurred in islands or archipelagoes with
deep water nearby, several appeared to have been associated with
acoustic waveguides like surface ducting, and the sound fields created
by ships transmitting MFAS (Cox et al., 2006; D'Spain et al., 2006).
Although Cuvier's beaked whales have been the most common species
involved in these stranding events (81 percent of the total number of
stranded animals), other beaked whales (including Mesoplodon europeaus,
M. densirostris, and Hyperoodon ampullatus) comprise 14 percent of the
total. Other species (Stenella coeruleoalba, Kogia breviceps and
Balaenoptera acutorostrata) have stranded, but in much lower numbers
and less consistently than beaked whales.
Based on the evidence available, however, NMFS cannot determine
whether (a) Cuvier's beaked whale is more prone to injury from high-
intensity sound than other species; (b) their behavioral responses to
sound makes them more likely to strand; or (c) they are more likely to
be exposed to MFAS than other cetaceans (for reasons that remain
unknown). Because the association between active sonar exposures and
marine mammals mass stranding events is not consistent--some marine
mammals strand without being exposed to sonar and some sonar
transmissions are not associated with marine mammal stranding events
despite their co-occurrence--other risk factors or a grouping of risk
factors probably contribute to these stranding events.

Behaviorally Mediated Responses to MFAS That May Lead To Stranding

Although the confluence of Navy MFAS with the other contributory
factors noted in the report was

[[Page 9975]]

identified as the cause of the 2000 Bahamas stranding event, the
specific mechanisms that led to that stranding (or the others) are not
understood, and there is uncertainty regarding the ordering of effects
that led to the stranding. It is unclear whether beaked whales were
directly injured by sound (e.g., acoustically mediated bubble growth,
as addressed above) prior to stranding or whether a behavioral response
to sound occurred that ultimately caused the beaked whales to be
injured and strand.
Although causal relationships between beaked whale stranding events
and active sonar remain unknown, several authors have hypothesized that
stranding events involving these species in the Bahamas and Canary
Islands may have been triggered when the whales changed their dive
behavior in a startled response to exposure to active sonar or to
further avoid exposure (Cox et al., 2006; Rommel et al., 2006). These
authors proposed three mechanisms by which the behavioral responses of
beaked whales upon being exposed to active sonar might result in a
stranding event. These include the following: Gas bubble formation
caused by excessively fast surfacing; remaining at the surface too long
when tissues are supersaturated with nitrogen; or diving prematurely
when extended time at the surface is necessary to eliminate excess
nitrogen. More specifically, beaked whales that occur in deep waters
that are in close proximity to shallow waters (for example, the
``canyon areas'' that are cited in the Bahamas stranding event; see
D'Spain and D'Amico, 2006), may respond to active sonar by swimming
into shallow waters to avoid further exposures and strand if they were
not able to swim back to deeper waters. Second, beaked whales exposed
to active sonar might alter their dive behavior. Changes in their dive
behavior might cause them to remain at the surface or at depth for
extended periods of time which could lead to hypoxia directly by
increasing their oxygen demands or indirectly by increasing their
energy expenditures (to remain at depth) and increase their oxygen
demands as a result. If beaked whales are at depth when they detect a
ping from an active sonar transmission and change their dive profile,
this could lead to the formation of significant gas bubbles, which
could damage multiple organs or interfere with normal physiological
function (Cox et al., 2006; Rommel et al., 2006; Zimmer and Tyack,
2007). Baird et al. (2005) found that slow ascent rates from deep dives
and long periods of time spent within 50 m of the surface were typical
for both Cuvier's and Blainville's beaked whales, the two species
involved in mass strandings related to naval sonar. These two
behavioral mechanisms may be necessary to purge excessive dissolved
nitrogen concentrated in their tissues during their frequent long dives
(Baird et al., 2005). Baird et al. (2005) further suggests that
abnormally rapid ascents or premature dives in response to high-
intensity sonar could indirectly result in physical harm to the beaked
whales, through the mechanisms described above (gas bubble formation or
non-elimination of excess nitrogen).
Because many species of marine mammals make repetitive and
prolonged dives to great depths, it has long been assumed that marine
mammals have evolved physiological mechanisms to protect against the
effects of rapid and repeated decompressions. Although several
investigators have identified physiological adaptations that may
protect marine mammals against nitrogen gas supersaturation (alveolar
collapse and elective circulation; Kooyman et al., 1972; Ridgway and
Howard, 1979), Ridgway and Howard (1979) reported that bottlenose
dolphins that were trained to dive repeatedly had muscle tissues that
were substantially supersaturated with nitrogen gas. Houser et al.
(2001) used these data to model the accumulation of nitrogen gas within
the muscle tissue of other marine mammal species and concluded that
cetaceans that dive deep and have slow ascent or descent speeds would
have tissues that are more supersaturated with nitrogen gas than other
marine mammals. Based on these data, Cox et al. (2006) hypothesized
that a critical dive sequence might make beaked whales more prone to
stranding in response to acoustic exposures. The sequence began with
(1) very deep (to depths as deep as 2 kilometers) and long (as long as
90 minutes) foraging dives; (2) relatively slow, controlled ascents;
and (3) a series of ``bounce'' dives between 100 and 400 m in depth
(also see Zimmer and Tyack, 2007). They concluded that acoustic
exposures that disrupted any part of this dive sequence (for example,
causing beaked whales to spend more time at surface without the bounce
dives that are necessary to recover from the deep dive) could produce
excessive levels of nitrogen supersaturation in their tissues, leading
to gas bubble and emboli formation that produces pathologies similar to
decompression sickness.
Zimmer and Tyack (2007) modeled nitrogen tension and bubble growth
in several tissue compartments for several hypothetical dive profiles
and concluded that repetitive shallow dives (defined as a dive where
depth does not exceed the depth of alveolar collapse, approximately 72
m for Ziphius), perhaps as a consequence of an extended avoidance
reaction to sonar sound, could pose a risk for decompression sickness
and that this risk should increase with the duration of the response.
Their models also suggested that unrealistically rapid ascent rates of
ascent from normal dive behaviors are unlikely to result in
supersaturation to the extent that bubble formation would be expected.
Tyack et al. (2006) suggested that emboli observed in animals exposed
to mid-frequency range sonar (Jepson et al., 2003; Fernandez et al.,
2005; Fern[aacute]ndez et al., 2012) could stem from a behavioral
response that involves repeated dives shallower than the depth of lung
collapse. Given that nitrogen gas accumulation is a passive process
(i.e. nitrogen is metabolically inert), a bottlenose dolphin was
trained to repetitively dive a profile predicted to elevate nitrogen
saturation to the point that nitrogen bubble formation was predicted to
occur. However, inspection of the vascular system of the dolphin via
ultrasound did not demonstrate the formation of asymptomatic nitrogen
gas bubbles (Houser et al., 2007). Baird et al. (2008), in a beaked
whale tagging study off Hawaii, showed that deep dives are equally
common during day or night, but ``bounce dives'' are typically a
daytime behavior, possibly associated with visual predator avoidance.
This may indicate that ``bounce dives'' are associated with something
other than behavioral regulation of dissolved nitrogen levels, which
would be necessary day and night.
If marine mammals respond to a Navy vessel that is transmitting
active sonar in the same way that they might respond to a predator,
their probability of flight responses should increase when they
perceive that Navy vessels are approaching them directly, because a
direct approach may convey detection and intent to capture (Burger and
Gochfeld, 1981, 1990; Cooper, 1997, 1998). The probability of flight
responses should also increase as received levels of active sonar
increase (and the ship is, therefore, closer) and as ship speeds
increase (that is, as approach speeds increase). For example, the
probability of flight responses in Dall's sheep (Ovis dalli dalli)
(Frid 2001a, b), ringed seals (Phoca hispida) (Born et al., 1999),
Pacific brant (Branta bernic nigricans) and Canada geese (B.
Canadensis) increased as a helicopter or

[[Page 9976]]

fixed-wing aircraft approached groups of these animals more directly
(Ward et al., 1999). Bald eagles (Haliaeetus leucocephalus) perched on
trees alongside a river were also more likely to flee from a paddle
raft when their perches were closer to the river or were closer to the
ground (Steidl and Anthony, 1996).
Despite the many theories involving bubble formation (both as a
direct cause of injury (see Acoustically Mediated Bubble Growth
Section) and an indirect cause of stranding (See Behaviorally Mediated
Bubble Growth Section), Southall et al., (2007) summarizes that there
is either scientific disagreement or a lack of information regarding
each of the following important points: (1) Received acoustical
exposure conditions for animals involved in stranding events; (2)
pathological interpretation of observed lesions in stranded marine
mammals; (3) acoustic exposure conditions required to induce such
physical trauma directly; (4) whether noise exposure may cause
behavioral reactions (such as atypical diving behavior) that
secondarily cause bubble formation and tissue damage; and (5) the
extent the post mortem artifacts introduced by decomposition before
sampling, handling, freezing, or necropsy procedures affect
interpretation of observed lesions.

Strandings in the GOA TMAA

Northern Edge--Prior to the start of Northern Edge 2015 (a joint
training exercise in the GOA TMAA hosted by Alaskan Command) and before
Navy vessels were in the Gulf of Alaska, the Navy was informed by NMFS
of various marine mammals found dead in the Gulf of Alaska and that
NMFS was attempting to obtain samples from them. It has been reported
that at least nine drifting and floating fin whales and multiple
pinniped species were found in Gulf of Alaska waters as early as May
23, 2015 between Kodiak Island to Unimak Pass. NMFS is still
investigating these findings but a possible cause referenced has been
an algal bloom. During Northern Edge 2015, two Navy vessels training in
the Gulf of Alaska on separate days encountered a well-decayed whale
carcass. This whale or whales may possibly be the same animal observed
by both ships, and given the stage of decomposition, might have been
one of the floating whales reported by other entities to NMFS before
Northern Edge began. The ships followed Navy reporting procedures and
the information was provided to NMFS to aid in the investigation. There
is no causal connection with Navy activities given the advanced stage
of decomposition and gap of timing of when Navy maritime training
events began.

Impulsive Sources

Underwater explosive detonations send a shock wave and sound energy
through the water and can release gaseous by-products, create an
oscillating bubble, or cause a plume of water to shoot up from the
water surface. The shock wave and accompanying noise are of most
concern to marine animals. Depending on the intensity of the shock wave
and size, location, and depth of the animal, an animal can be injured,
killed, suffer non-lethal physical effects, experience hearing related
effects with or without behavioral responses, or exhibit temporary
behavioral responses or tolerance from hearing the blast sound.
Generally, exposures to higher levels of impulse and pressure levels
would result in greater impacts to an individual animal.
Injuries resulting from a shock wave take place at boundaries
between tissues of different densities. Different velocities are
imparted to tissues of different densities, and this can lead to their
physical disruption. Blast effects are greatest at the gas-liquid
interface (Landsberg, 2000). Gas-containing organs, particularly the
lungs and gastrointestinal tract, are especially susceptible (Goertner,
1982; Hill, 1978; Yelverton et al., 1973). In addition, gas-containing
organs including the nasal sacs, larynx, pharynx, trachea, and lungs
may be damaged by compression/expansion caused by the oscillations of
the blast gas bubble (Reidenberg and Laitman, 2003). Intestinal walls
can bruise or rupture, with subsequent hemorrhage and escape of gut
contents into the body cavity. Less severe gastrointestinal tract
injuries include contusions, petechiae (small red or purple spots
caused by bleeding in the skin), and slight hemorrhaging (Yelverton et
al., 1973).
Because the ears are the most sensitive to pressure, they are the
organs most sensitive to injury (Ketten, 2000). Sound-related damage
associated with sound energy from detonations can be theoretically
distinct from injury from the shock wave, particularly farther from the
explosion. If a noise is audible to an animal, it has the potential to
damage the animal's hearing by causing decreased sensitivity (Ketten,
1995). Sound-related trauma can be lethal or sublethal. Lethal impacts
are those that result in immediate death or serious debilitation in or
near an intense source and are not, technically, pure acoustic trauma
(Ketten, 1995). Sublethal impacts include hearing loss, which is caused
by exposures to perceptible sounds. Severe damage (from the shock wave)
to the ears includes tympanic membrane rupture, fracture of the
ossicles, damage to the cochlea, hemorrhage, and cerebrospinal fluid
leakage into the middle ear. Moderate injury implies partial hearing
loss due to tympanic membrane rupture and blood in the middle ear.
Permanent hearing loss also can occur when the hair cells are damaged
by one very loud event, as well as by prolonged exposure to a loud
noise or chronic exposure to noise. The level of impact from blasts
depends on both an animal's location and, at outer zones, on its
sensitivity to the residual noise (Ketten, 1995).
There have been fewer studies addressing the behavioral effects of
explosives on marine mammals compared to MFAS/HFAS. However, though the
nature of the sound waves emitted from an explosion are different (in
shape and rise time) from MFAS/HFAS, NMFS still anticipates the same
sorts of behavioral responses to result from repeated explosive
detonations (a smaller range of likely less severe responses (i.e., not
rising to the level of MMPA harassment) would be expected to occur as a
result of exposure to a single explosive detonation that was not
powerful enough or close enough to the animal to cause TTS or injury).
Baleen whales have shown a variety of responses to impulse sound
sources, including avoidance, reduced surface intervals, altered
swimming behavior, and changes in vocalization rates (Richardson et
al., 1995; Gordon et al., 2003; Southall, 2007). While most bowhead
whales did not show active avoidance until within 8 km of seismic
vessels (Richardson et al., 1995), some whales avoided vessels by more
than 20 km at received levels as low as 120 dB re 1 [mu]Pa rms.
Additionally, Malme et al. (1988) observed clear changes in diving and
respiration patterns in bowheads at ranges up to 73 km from seismic
vessels, with received levels as low as 125 dB re 1 [mu]Pa.
Gray whales migrating along the U.S. west coast showed avoidance
responses to seismic vessels by 10 percent of animals at 164 dB re 1
[mu]Pa, and by 90 percent of animals at 190 dB re 1 [mu]Pa, with
similar results for whales in the Bering Sea (Malme 1986, 1988). In
contrast, noise from seismic surveys was not found to impact feeding
behavior or exhalation rates while resting or diving in western gray
whales off the coast of Russia (Yazvenko et al., 2007; Gailey et al.,
2007).

[[Page 9977]]

Humpback whales showed avoidance behavior at ranges of 5-8 km from
a seismic array during observational studies and controlled exposure
experiments in western Australia (McCauley, 1998; Todd et al., 1996)
found no clear short-term behavioral responses by foraging humpbacks to
explosions associated with construction operations in Newfoundland, but
did see a trend of increased rates of net entanglement and a shift to a
higher incidence of net entanglement closer to the noise source.
Seismic pulses at average received levels of 131 dB re 1
micropascal squared second ([mu]Pa\2\-s) caused blue whales to increase
call production (Di Iorio and Clark, 2010). In contrast, McDonald et
al. (1995) tracked a blue whale with seafloor seismometers and reported
that it stopped vocalizing and changed its travel direction at a range
of 10 km from the seismic vessel (estimated received level 143 dB re 1
[mu]Pa peak-to-peak). These studies demonstrate that even low levels of
noise received far from the noise source can induce behavioral
responses.
Madsen et al. (2006) and Miller et al. (2009) tagged and monitored
eight sperm whales in the Gulf of Mexico exposed to seismic airgun
surveys. Sound sources were from approximately 2 to 7 nm away from the
whales and based on multipath propagation received levels were as high
as 162 dB SPL re 1 [mu]Pa with energy content greatest between 0.3 and
3.0 kHz (Madsen, 2006). The whales showed no horizontal avoidance,
although the whale that was approached most closely had an extended
resting period and did not resume foraging until the airguns had ceased
firing (Miller et al., 2009). The remaining whales continued to execute
foraging dives throughout exposure; however, swimming movements during
foraging dives were 6 percent lower during exposure than control
periods, suggesting subtle effects of noise on foraging behavior
(Miller et al., 2009). Captive bottlenose dolphins sometimes vocalized
after an exposure to impulse sound from a seismic watergun (Finneran et
al., 2010a).
A review of behavioral reactions by pinnipeds to impulse noise can
be found in Richardson et al. (1995) and Southall et al. (2007).
Blackwell et al. (2004) observed that ringed seals exhibited little or
no reaction to pipe-driving noise with mean underwater levels of 157 dB
re 1 [mu]Pa rms and in air levels of 112 dB re 20 [mu]Pa, suggesting
that the seals had habituated to the noise. In contrast, captive
California sea lions avoided sounds from an impulse source at levels of
165-170 dB re 1 [mu]Pa (Finneran et al., 2003b). Experimentally,
G[ouml]tz and Janik (2011) tested underwater, startle responses to a
startling sound (sound with a rapid rise time and a 93 dB sensation
level [the level above the animal's threshold at that frequency]) and a
non-startling sound (sound with the same level, but with a slower rise
time) in wild-captured gray seals. The animals exposed to the startling
treatment avoided a known food source, whereas animals exposed to the
non-startling treatment did not react or habituated during the exposure
period. The results of this study highlight the importance of the
characteristics of the acoustic signal in an animal's response of
habituation.

Vessels

Ship strikes of cetaceans can cause major wounds, which may lead to
the death of the animal. An animal at the surface could be struck
directly by a vessel, a surfacing animal could hit the bottom of a
vessel, or an animal just below the surface could be cut by a vessel's
propeller. The severity of injuries typically depends on the size and
speed of the vessel (Knowlton and Kraus, 2001; Laist et al., 2001;
Vanderlaan and Taggart, 2007). The most vulnerable marine mammals are
those that spend extended periods of time at the surface in order to
restore oxygen levels within their tissues after deep dives (e.g., the
sperm whale). In addition, some baleen whales, such as the North
Atlantic right whale, seem generally unresponsive to vessel sound,
making them more susceptible to vessel collisions (Nowacek et al.,
2004). These species are primarily large, slow moving whales. Smaller
marine mammals (e.g., bottlenose dolphin) move quickly through the
water column and are often seen riding the bow wave of large ships.
Marine mammal responses to vessels may include avoidance and changes in
dive pattern (NRC, 2003).
An examination of all known ship strikes from all shipping sources
(civilian and military) indicates vessel speed is a principal factor in
whether a vessel strike results in death (Knowlton and Kraus, 2001;
Laist et al., 2001; Jensen and Silber, 2003; Vanderlaan and Taggart,
2007). In assessing records in which vessel speed was known, Laist et
al. (2001) found a direct relationship between the occurrence of a
whale strike and the speed of the vessel involved in the collision. The
authors concluded that most deaths occurred when a vessel was traveling
in excess of 13 knots.
Jensen and Silber (2003) detailed 292 records of known or probable
ship strikes of all large whale species from 1975 to 2002. Of these,
vessel speed at the time of collision was reported for 58 cases. Of
these cases, 39 (or 67 percent) resulted in serious injury or death (19
of those resulted in serious injury as determined by blood in the
water, propeller gashes or severed tailstock, and fractured skull, jaw,
vertebrae, hemorrhaging, massive bruising or other injuries noted
during necropsy and 20 resulted in death). Operating speeds of vessels
that struck various species of large whales ranged from 2 to 51 knots.
The majority (79 percent) of these strikes occurred at speeds of 13
knots or greater. The average speed that resulted in serious injury or
death was 18.6 knots. Pace and Silber (2005) found that the probability
of death or serious injury increased rapidly with increasing vessel
speed. Specifically, the predicted probability of serious injury or
death increased from 45 to 75 percent as vessel speed increased from 10
to 14 knots, and exceeded 90 percent at 17 knots. Higher speeds during
collisions result in greater force of impact and also appear to
increase the chance of severe injuries or death. While modeling studies
have suggested that hydrodynamic forces pulling whales toward the
vessel hull increase with increasing speed (Clyne, 1999; Knowlton et
al., 1995), this is inconsistent with Silber et al. (2010), which
demonstrated that there is no such relationship (i.e., hydrodynamic
forces are independent of speed).
The Jensen and Silber (2003) report notes that the database
represents a minimum number of collisions, because the vast majority
probably goes undetected or unreported. In contrast, Navy vessels are
likely to detect any strike that does occur, and they are required to
report all ship strikes involving marine mammals. Overall, the
percentages of Navy traffic relative to overall large shipping traffic
are very small (on the order of 2 percent).
There are no records of any Navy vessel strikes to marine mammals
during training or testing activities in the Study Area. There have
been Navy vessel strikes of large whales in areas outside the Study
Area, such as Hawaii and Southern California. However, these areas
differ significantly from the Study Area given that both Hawaii and
Southern California have a much higher number of Navy vessel activities
and much higher densities of large whales.
Other efforts have been undertaken to investigate the impact from
vessels (both whale-watching and general vessel traffic noise) and
demonstrated impacts do occur (Bain, 2002; Erbe, 2002; Lusseau, 2009;
Williams et al., 2006, 2009, 2011b, 2013, 2014a, 2014b; Noren

[[Page 9978]]

et al., 2009; Read et al., 2014; Rolland et al., 2012; Pirotta et al.,
2015). This body of research for the most part has investigated impacts
associated with the presence of chronic stressors, which differ
significantly from generally intermittent Navy training and testing
activities. For example, in an analysis of energy costs to killer
whales, Williams et al. (2009) suggested that whale-watching in the
Johnstone Strait resulted in lost feeding opportunities due to vessel
disturbance, which could carry higher costs than other measures of
behavioral change might suggest. Ayres et al. (2012) recently reported
on research in the Salish Sea involving the measurement of southern
resident killer whale fecal hormones to assess two potential threats to
the species recovery: Lack of prey (salmon) and impacts to behavior
from vessel traffic. Ayres et al. (2012) suggested that the lack of
prey overshadowed any population-level physiological impacts on
southern resident killer whales from vessel traffic.
Based on the implementation of Navy mitigation measures and the low
density of Navy ships in the GOA TMAA, NMFS has concluded,
preliminarily, that the probability of a ship strike is very low,
especially for dolphins and porpoises, killer whales, social pelagic
odontocetes and pinnipeds that are highly visible, and/or comparatively
small and maneuverable. Though more probable because of their size,
NMFS also believes that the likelihood of a Navy vessel striking a
mysticete or sperm whale is also low with the implementation of
mitigation measures and the low density of navy ships in the Study
Area. The Navy did not request take from a ship strike, and based on
our preliminary determination, NMFS is not recommending that they
modify their request at this time. However, both NMFS and the Navy are
currently engaged in a Section 7 consultation under the ESA, and that
consultation will further inform our final decision.

Proposed Mitigation

Under section 101(a)(5)(A) of the MMPA, NMFS must set forth the
``permissible methods of taking pursuant to such activity, and other
means of effecting the least practicable adverse impact on such species
or stock and its habitat, paying particular attention to rookeries,
mating grounds, and areas of similar significance.'' NMFS' duty under
this ``least practicable adverse impact'' standard is to prescribe
mitigation reasonably designed to minimize, to the extent practicable,
any adverse population-level impacts, as well as habitat impacts. While
population-level impacts are minimized by reducing impacts on
individual marine mammals, not all takes have a reasonable potential
for translating to population-level impacts. NMFS' objective under the
``least practicable adverse impact'' standard is to design mitigation
targeting those impacts on individual marine mammals that are
reasonably likely to contribute to adverse population-level effects.
The NDAA of 2004 amended the MMPA as it relates to military
readiness activities and the ITA process such that ``least practicable
adverse impact'' shall include consideration of personnel safety,
practicality of implementation, and impact on the effectiveness of the
``military readiness activity.'' The training and testing activities
described in the Navy's LOA application are considered military
readiness activities.
In Conservation Council for Hawaii v. National Marine Fisheries
Service, No. 1:13-cv-00684 (D. Hawaii March 31, 2015), the court stated
that NMFS ``appear[s] to think that [it] satisf[ies] the statutory
`least practicable adverse impact' requirement with a `negligible
impact' finding.'' In light of the court's decision, we take this
opportunity to make clear our position that the ``negligible impact''
and ``least practicable adverse impact'' requirements are distinct,
even though the focus of both is on population-level impacts.
A population-level impact is an impact on the population numbers
(survival) or growth and reproductive rates (recruitment) of a
particular marine mammal species or stock. As we noted in the preamble
to our general MMPA implementing regulations, not every population-
level impact violates the negligible impact requirement. As we
explained, the negligible impact standard does not require a finding
that the anticipated take will have ``no effect'' on population numbers
or growth rates: ``The statutory standard does not require that the
same recovery rate be maintained, rather that no significant effect on
annual rates of recruitment or survival occurs . . . [T]he key factor
is the significance of the level of impact on rates of recruitment or
survival. Only insignificant impacts on long-term population levels and
trends can be treated as negligible.'' See 54 FR 40338, 40341-42
(September 29, 1989). Nevertheless, while insignificant impacts on
population numbers or growth rates may satisfy the negligible impact
requirement, such impacts still must be mitigated, to the extent
practicable, under the ``least practicable adverse impact''
requirement. Thus, the negligible impact and least practicable adverse
impact requirements are clearly distinct, even though both focus on
population-level effects.
Any mitigation measure(s) prescribed by NMFS should be able to
accomplish, have a reasonable likelihood of accomplishing (based on
current science), or contribute to accomplishing one or more of the
general goals listed below:
a. Avoid or minimize injury or death of marine mammals wherever
possible (goals b, c, and d may contribute to this goal).
b. Reduce the numbers of marine mammals (total number or number at
biologically important time or location) exposed to received levels of
MFAS/HFAS, underwater detonations, or other activities expected to
result in the take of marine mammals (this goal may contribute to a,
above, or to reducing harassment takes only).
c. Reduce the number of times (total number or number at
biologically important time or location) individuals would be exposed
to received levels of MFAS/HFAS, underwater detonations, or other
activities expected to result in the take of marine mammals (this goal
may contribute to a, above, or to reducing harassment takes only).
d. Reduce the intensity of exposures (either total number or number
at biologically important time or location) to received levels of MFAS/
HFAS, underwater detonations, or other activities expected to result in
the take of marine mammals (this goal may contribute to a, above, or to
reducing the severity of harassment takes only).
e. Avoid or minimize adverse effects to marine mammal habitat
(including acoustic habitat), paying special attention to the food
base, activities that block or limit passage to or from biologically
important areas, permanent destruction of habitat, or temporary
destruction/disturbance of habitat during a biologically important
time.
f. For monitoring directly related to mitigation--increase the
probability of detecting marine mammals, thus allowing for more
effective implementation of the mitigation (shut-down zone, etc.).
Our final evaluation of measures that meet one or more of the above
goals includes consideration of the following factors in relation to
one another: The manner in which, and the degree to which, the
successful implementation of the mitigation measures is expected to
reduce population-level impacts to marine mammal species and stocks and
impacts to their habitat; the proven or likely efficacy of the
measures; and the practicability of the suite of measures

[[Page 9979]]

for applicant implementation, including consideration of personnel
safety, practicality of implementation, and impact on the effectiveness
of the military readiness activity.
NMFS reviewed the proposed activities and the suite of proposed
mitigation measures as described in the Navy's LOA application to
determine if they would result in the least practicable adverse effect
on marine mammals. NMFS worked with the Navy in the development of the
Navy's initially proposed measures, which are informed by years of
experience and monitoring. Below are the mitigation measures as agreed
upon by the Navy and NMFS. For additional details regarding the Navy's
mitigation measures, see Chapter 5 in the GOA DSEIS/OEIS.

Lookouts

The Navy will have two types of Lookouts for the purposes of
conducting visual observations: Those positioned on ships; and those
positioned ashore, in aircraft, or on small boats. Lookouts positioned
on ships will diligently observe the air and surface of the water. They
will have multiple observation objectives, which include but are not
limited to detecting the presence of biological resources and
recreational or fishing boats, observing the mitigation zones, and
monitoring for vessel and personnel safety concerns.
Due to manning and space restrictions on aircraft, small boats, and
some Navy ships, Lookouts for these platforms may be supplemented by
the aircraft crew or pilot, boat crew, range site personnel, or shore-
side personnel. Lookouts positioned in minimally manned platforms may
be responsible for tasks in addition to observing the air or surface of
the water (e.g., navigation of a helicopter or small boat). However,
all Lookouts will, considering personnel safety, practicality of
implementation, and impact on the effectiveness of the activity, comply
with the observation objectives described above for Lookouts positioned
on ships.
The procedural measures described in the remainder of this section
primarily consist of having Lookouts during specific training
activities.
All personnel standing watch on the bridge, Commanding Officers,
Executive Officers, maritime patrol aircraft aircrews, anti-submarine
warfare helicopter crews, civilian equivalents, and Lookouts will
successfully complete the United States Navy Marine Species Awareness
Training prior to standing watch or serving as a Lookout. Additional
details on the Navy's Marine Species Awareness Training can be found in
the GOA DSEIS/OEIS. The Navy proposes to use one or more Lookouts
during the training activities described below, which are organized by
stressor category.
Non-Impulsive Sound

Hull Mounted Mid-Frequency Active Sonar

The Navy's current Lookout mitigation measures during training
activities involving hull-mounted MFAS include requirements such as the
number of personnel on watch and the manner in which personnel are to
visually search the area in the vicinity of the ongoing activity.
The Navy is proposing to maintain the number of Lookouts currently
implemented for ships using hull-mounted MFAS. Ships using hull-mounted
MFAS sources associated with ASW activities at sea (with the exception
of ships less than 65 ft. [20 m] in length, which are minimally manned)
will have two Lookouts at the forward position. While using hull-
mounted MFAS sources underway, vessels less than 65 ft. [20 m] in
length and ships that are minimally manned will have one Lookout at the
forward position due to space and manning restrictions.

High-Frequency and Non-Hull-Mounted Mid-Frequency Active Sonar

The Navy currently conducts activities using high-frequency and
non-hull-mounted MFAS in the Study Area. Non-hull-mounted MFAS training
activities include the use of aircraft deployed sonobuoys, helicopter
dipping sonar, and submarine sonar. During those activities, the Navy
employs the following mitigation measures regarding Lookout procedures:
Navy aircraft participating in exercises at sea shall
conduct and maintain, when operationally feasible and safe,
surveillance for marine species of concern as long as it does not
violate safety constraints or interfere with the accomplishment of
primary operational duties.
Helicopters shall observe/survey the vicinity of an ASW
training event for 10 minutes before the first deployment of active
(dipping) sonar in the water.
The Navy is proposing to continue using the number of Lookouts
(one) currently implemented for aircraft conducting non-hull-mounted
MFA sonar activities.
Mitigation measures do not currently exist for other high-frequency
active sonar activities associated with ASW, or for new platforms;
therefore, the Navy is proposing to add a new Lookout and other
measures for these activities and on these platforms when conducted in
the Study Area. The recommended measure is provided below.
The Navy will have one Lookout on ships conducting high-frequency
or non-hull mounted mid-frequency active sonar activities associated
with ASW activities at sea.
Explosives and Impulsive Sound

Improved Extended Echo Ranging Sonobuoys

The Navy is not proposing use of Improved Extended Echo Ranging
Sonobuoys during the GOA TMAA training activities.

Explosive Signal Underwater Sound Buoys Using >0.5-2.5 Pound Net
Explosive Weight

Lookout measures do not currently exist for explosive signal
underwater sound (SUS) buoy activities using >0.5-2.5 pound (lb.) net
explosive weight (NEW). The Navy is proposing to add this measure.
Aircraft conducting SUS activities using >0.5-2.5 lb. NEW will have one
Lookout.

Gunnery Exercises--Small-, Medium-, and Large-Caliber Using a Surface
Target

Currently, the Navy employs the following Lookout procedures during
gunnery exercises:
From the intended firing position, trained Lookouts shall
survey the mitigation zone for marine mammals prior to commencement and
during the exercise as long as practicable.
If applicable, target towing vessels shall maintain a
Lookout. If a marine mammal is sighted in the vicinity of the exercise,
the tow vessel shall immediately notify the firing vessel in order to
secure gunnery firing until the area is clear.
The Navy is proposing to continue using the Lookout procedures
currently implemented for this activity. The Navy will have one Lookout
on the vessel or aircraft conducting small-, medium-, or large-caliber
gunnery exercises against a surface target. Towing vessels, if
applicable, shall also maintain one Lookout.

Missile Exercises Using a Surface Target

Currently, the Navy employs the following Lookout procedures during
missile exercises:
Aircraft shall visually survey the target area for marine
mammals. Visual inspection of the target area shall be made by flying
at 1,500 ft. (457 m) or lower, if safe to do so, and at slowest safe
speed.

[[Page 9980]]

Firing or range clearance aircraft must be able to
actually see ordnance impact areas.
The Navy is proposing to continue using the Lookout procedures
currently implemented for this activity. When aircraft are conducting
missile exercises against a surface target, the Navy will have one
Lookout positioned in an aircraft.

Bombing Exercises (Explosive)

Currently, the Navy employs the following Lookout procedures during
bombing exercises:
If surface vessels are involved, Lookouts shall survey for
floating kelp and marine mammals.
Aircraft shall visually survey the target and buffer zone
for marine mammals prior to and during the exercise. The survey of the
impact area shall be made by flying at 1,500 ft. (460 m) or lower, if
safe to do so, and at the slowest safe speed. Release of ordnance
through cloud cover is prohibited: Aircraft must be able to actually
see ordnance impact areas. Survey aircraft should employ most effective
search tactics and capabilities.
The Navy is proposing to (1) continue implementing the current
measures for bombing exercises, and (2) clarify the number of Lookouts
currently implemented for this activity. The Navy will have one Lookout
positioned in an aircraft conducting bombing exercises, and trained
Lookouts in any surface vessels involved.

Weapons Firing Noise During Gunnery Exercises

The Navy is proposing to continue using the number of Lookouts
currently implemented for gunnery exercises. The Navy will have one
Lookout on the ship conducting explosive and non-explosive gunnery
exercises. This may be the same Lookout described for Gunnery
Exercises--Small-, Medium-, and Large-Caliber Using a Surface Target
when that activity is conducted from a ship against a surface target.

Sinking Exercises

The Navy is proposing to continue using the number of Lookouts
currently implemented for this activity. The Navy will have two
Lookouts (one positioned in an aircraft and one on a vessel) during
sinking exercises.
Physical Disturbance and Strike

Vessels

Currently, the Navy employs the following Lookout procedures to
avoid physical disturbance and strike of marine mammals during at-sea
training:
While underway, surface vessels shall have at least two
Lookouts with binoculars; surfaced submarines shall have at least one
Lookout with binoculars. Lookouts already posted for safety of
navigation and man-overboard precautions may be used to fill this
requirement. As part of their regular duties, Lookouts will watch for
and report to the Officer of the Deck the presence of marine mammals.
Consistent with other ongoing Navy Phase 2 training and testing
(NWTT, MITT, AFTT, HSTT), the Navy is proposing to revise the
mitigation measures for this activity as follows: While underway,
vessels will have a minimum of one Lookout.
Non-Explosive Practice Munitions

Gunnery Exercises--Small-, Medium-, and Large-Caliber Using a Surface
Target

Currently, the Navy employs the same mitigation measures for non-
explosive practice munitions--small-, medium-, and large-caliber
gunnery exercises--as described above for Gunnery Exercises--Small-,
Medium-, and Large-Caliber Using a Surface Target.
The Navy is proposing to continue using the number of Lookouts
currently implemented for these activities. The Navy will have one
Lookout during activities involving non-explosive practice munitions
(e.g., small-, medium-, and large-caliber gunnery exercises) against a
surface target.

Missile Exercises Using a Surface Target

Currently, the Navy employs the same mitigation measures for non-
explosive missile exercises (including rockets) using a surface target
as described for Missile Exercises Using a Surface Target (explosive).
The Navy is proposing to continue using the number of Lookouts
currently implemented for these activities. When aircraft are
conducting non-explosive missile exercises (including exercises using
rockets) against a surface target, the Navy will have one Lookout
positioned in an aircraft.

Bombing Exercises

Currently, the Navy employs the same mitigation measures for non-
explosive bombing exercises as described for Bombing Exercises
(Explosive).
The Navy is proposing to continue using the same Lookout procedures
currently implemented for these activities. The Navy will have one
Lookout positioned in an aircraft during non-explosive bombing
exercises, and trained Lookouts in any surface vessels involved.

Mitigation Zones

The Navy proposes to use mitigation zones to reduce the potential
impacts to marine mammals from training activities. Mitigation zones
are measured as the radius from a source. Unique to each activity
category, each radius represents a distance that the Navy will visually
observe to help reduce injury to marine species. Visual detections of
applicable marine species will be communicated immediately to the
appropriate watch station for information dissemination and appropriate
action. If the presence of marine mammals is detected acoustically,
Lookouts posted in aircraft and on surface vessels will increase the
vigilance of their visual surveillance. As a reference, aerial surveys
are typically made by flying at 1,500 ft. (457 m) altitude or lower at
the slowest safe speed.
Many of the proposed activities have mitigation measures that are
currently being implemented, as required by previous environmental
documents or consultations. Most of the current mitigation zones for
activities that involve the use of impulsive and non-impulsive sources
were originally designed to reduce the potential for onset of TTS. For
the GOA DSEIS/OEIS and the LOA application, the Navy updated the
acoustic propagation modeling to incorporate updated hearing threshold
metrics (i.e., upper and lower frequency limits), updated density data
for marine mammals, and factors such as an animal's likely presence at
various depths. An explanation of the acoustic propagation modeling
process can be found in the Determination of Acoustic Effects on Marine
Mammals for the Gulf of Alaska Training Supplemental Environmental
Impact Statement/Overseas Environmental Impact Statement technical
report (Marine Species Modeling Team, 2014).
As a result of the updates to the acoustic propagation modeling, in
some cases the ranges to onset of TTS effects are much larger than
previous model outputs. Due to the ineffectiveness and unacceptable
operational impacts associated with mitigating these large areas, the
Navy is unable to mitigate for onset of TTS for every activity. In this
GOA TMAA analysis, the Navy developed each recommended mitigation zone
to avoid or reduce the potential for onset PTS, out to the predicted
maximum range. In some cases where the ranges to effects are smaller
than previous models estimated, the mitigation zones were adjusted
accordingly to provide consistency

[[Page 9981]]

across the measures. Mitigating to the predicted maximum range to PTS
consequently also mitigates to the predicted maximum range to onset
mortality (1 percent mortality), onset slight lung injury, and onset
slight gastrointestinal tract injury, since the maximum range to
effects for these criteria are shorter than for PTS. Furthermore, in
most cases, the predicted maximum range to PTS also consequently covers
the predicted average range to TTS. Table 8 summarizes the predicted
average range to TTS, average range to PTS, maximum range to PTS, and
recommended mitigation zone for each activity category, based on the
Navy's acoustic propagation modeling results.
The activity-specific mitigation zones are based on the longest
range for all the functional hearing groups. The mitigation zone for a
majority of activities is driven by either the high-frequency cetaceans
or the sea turtles functional hearing groups. Therefore, the mitigation
zones are even more protective for the remaining functional hearing
groups (i.e., low-frequency cetaceans, mid-frequency cetaceans, and
pinnipeds), and likely cover a larger portion of the potential range to
onset of TTS.
This evaluation includes explosive ranges to TTS and the onset of
auditory injury, non-auditory injury, slight lung injury, and
mortality. For every source proposed for use by the Navy, the
recommended mitigation zones included in Table 8 exceed each of these
ranges. In some instances, the Navy recommends mitigation zones that
are larger or smaller than the predicted maximum range to PTS based on
the effectiveness and operational assessments. The recommended
mitigation zones and their associated assessments are provided
throughout the remainder of this section. The recommended measures are
either currently implemented, are modifications of current measures, or
are new measures.
For some activities specified throughout the remainder of this
section, Lookouts may be required to observe for concentrations of
detached floating vegetation (Sargassum or kelp paddies), which are
indicators of potential marine mammal presence within the mitigation
zone. Those specified activities will not commence if floating
vegetation (Sargassum or kelp paddies) is observed within the
mitigation zone prior to the initial start of the activity. If floating
vegetation is observed prior to the initial start of the activity, the
activity will be relocated to an area where no floating vegetation is
observed. Training will not cease as a result of indicators entering
the mitigation zone after activities have commenced. This measure is
intended only for floating vegetation detached from the seafloor.

Table 8--Predicted Ranges to Effects and Recommended Mitigation Zones for Each Activity Category
--------------------------------------------------------------------------------------------------------------------------------------------------------
Representative source Predicted (longest) Predicted (longest) Predicted maximum Recommended
Activity category (bin) \1\ average range to TTS average range to PTS range to PTS mitigation zone
--------------------------------------------------------------------------------------------------------------------------------------------------------
Non-Impulse Sound
--------------------------------------------------------------------------------------------------------------------------------------------------------
Hull-Mounted Mid[dash]Frequency SQS-53 ASW hull- 3,821 yd. (3.5 km) for 100 yd. (91 m) for Not Applicable....... 6 dB power down at
Active Sonar. mounted sonar (MF1). one ping. one ping. 1,000 yd. (914 m); 4
dB power down at 500
yd. (457 m); and
shutdown at 200 yd.
(183 m).
High-Frequency and Non[dash]Hull AQS-22 ASW dipping 230 yd. (210 m) for 20 yd. (18 m) for one Not applicable....... 200 yd. (183 m).
Mounted Mid[dash]Frequency Active sonar (MF4). one ping. ping.
Sonar.
--------------------------------------------------------------------------------------------------------------------------------------------------------
Explosive and Impulse Sound
--------------------------------------------------------------------------------------------------------------------------------------------------------
Signal Underwater Sound (SUS) buoys Explosive sonobuoy 290 yd. (265 m)....... 113 yd. (103 m)...... 309 yd. (283 m)...... 350 yd. (320 m).
using > 0.5-2.5 lb. NEW. (E3).
Gunnery Exercises--Small- and 40 mm projectile (E2). 190 yd. (174 m)....... 83 yd. (76 m)........ 182 yd. (167 m)...... 200 yd. (183 m).
Medium-Caliber (Surface Target).
Gunnery Exercises--Large-Caliber 5 in. projectiles (E5) 453 yd. (414 m)....... 186 yd. (170 m)...... 526 yd. (481 m)...... 600 yd. (549 m).
(Surface Target).
Missile Exercises (Including Maverick missile (E9). 949 yd. (868 m)....... 398 yd. (364 m)...... 699 yd. (639 m)...... 900 yd. (823 m).
Rockets) up to 250 lb. NEW Using a
Surface Target.
Missile Exercises up to 500 lb. NEW Harpoon missile (E10). 1,832 yd. (1.7 km).... 731 yd. (668 m)...... 1,883 yd. (1.7 km)... 2,000 yd. (1.8 km).
(Surface Target).
Bombing Exercises.................. MK-84 2,000 lb. bomb 2,513 yd. (2.3 km).... 991 yd. (906 m)...... 2,474 yd. (2.3 km)... 2,500 yd. (2.3
(E12). km)\2\.
Sinking Exercises.................. Various up to MK-84 2,513 yd. (2.3 km).... 991 yd. (906 m)...... 2,474 yd. (2.3 km)... 2.5 nm \(2)\.
2,000 lb. bomb (E12).
--------------------------------------------------------------------------------------------------------------------------------------------------------
\1\ This table does not provide an inclusive list of source bins; bins presented here represent the source bin with the largest range to effects within
the given activity category.
\2\ Recommended mitigation zones are larger than the modeled injury zones to account for multiple types of sources or charges being used.
Notes: in = inches, km = kilometers, lb. = pounds, m = meters, nm = nautical miles, PTS = Permanent Threshold Shift, TTS = Temporary Threshold Shift,
yd. = yards

[[Page 9982]]

Non-Impulsive Sound

Hull-Mounted Mid-Frequency Active Sonar

The Navy is proposing to (1) continue implementing the current
measures for MFAS and (2) to clarify the conditions needed to
recommence an activity after a marine mammal has been detected.
Activities that involve the use of hull-mounted MFA sonar will use
Lookouts for visual observation from a ship immediately before and
during the activity. Mitigation zones for these activities involve
powering down the sonar by 6 dB when a marine mammal is sighted within
1,000 yd. (914 m) of the sonar dome, and by an additional 4 dB when
sighted within 500 yd. (457 m) from the source, for a total reduction
of 10 dB. Active transmissions will cease if a marine mammal is sighted
within 200 yd. (183 m). Active transmission will recommence if any one
of the following conditions is met: (1) The animal is observed exiting
the mitigation zone, (2) the animal is thought to have exited the
mitigation zone based on its course and speed, (3) the mitigation zone
has been clear from any additional sightings for a period of 30
minutes, (4) the ship has transited more than 2,000 yd. (1.8 km) beyond
the location of the last sighting, or (5) the ship concludes that
dolphins are deliberately closing in on the ship to ride the ship's bow
wave (and there are no other marine mammal sightings within the
mitigation zone). Active transmission may resume when dolphins are bow
riding because they are out of the main transmission axis of the active
sonar while in the shallow-wave area of the ship bow.

High-Frequency and Non-Hull-Mounted Mid-Frequency Active Sonar

Non-hull-mounted MFA sonar training activities include the use of
aircraft deployed sonobuoys and helicopter dipping sonar. The Navy is
proposing to: (1) Continue implementing the current mitigation measures
for activities currently being executed, such as dipping sonar
activities; (2) extend the implementation of its current mitigation to
all other activities in this category; and (3) clarify the conditions
needed to recommence an activity after a sighting. The recommended
measures are provided below.
Mitigation will include visual observation from a vessel or
aircraft (with the exception of platforms operating at high altitudes)
immediately before and during active transmission within a mitigation
zone of 200 yd. (183 m) from the active sonar source. For activities
involving helicopter deployed dipping sonar, visual observation will
commence 10 minutes before the first deployment of active dipping
sonar. Helicopter dipping and sonobuoy deployment will not begin if
concentrations of floating vegetation (kelp paddies), are observed in
the mitigation zone. If the source can be turned off during the
activity, active transmission will cease if a marine mammal is sighted
within the mitigation zone. Active transmission will recommence if any
one of the following conditions is met: (1) The animal is observed
exiting the mitigation zone, (2) the animal is thought to have exited
the mitigation zone based on its course and speed, (3) the mitigation
zone has been clear from any additional sightings for a period of 10
minutes for an aircraft-deployed source, (4) the mitigation zone has
been clear from any additional sightings for a period of 30 minutes for
a vessel-deployed source, (5) the vessel or aircraft has repositioned
itself more than 400 yd. (370 m) away from the location of the last
sighting, or (6) the vessel concludes that dolphins are deliberately
closing in to ride the vessel's bow wave (and there are no other marine
mammal sightings within the mitigation zone).
Explosives and Impulsive Sound

Explosive Signal Underwater Sound Buoys Using >0.5-2.5 Pound Net
Explosive Weight

Mitigation measures do not currently exist for activities using
explosive signal underwater sound (SUS) buoys.
The Navy is proposing to add the following recommended measures.
Mitigation will include pre-exercise aerial monitoring during
deployment within a mitigation zone of 350 yd. (320 m) around an
explosive SUS buoy. Explosive SUS buoys will not be deployed if
concentrations of floating vegetation (kelp paddies) are observed in
the mitigation zone (around the intended deployment location). SUS
deployment will cease if a marine mammal is sighted within the
mitigation zone. Deployment will recommence if any one of the following
conditions is met: (1) The animal is observed exiting the mitigation
zone, (2) the animal is thought to have exited the mitigation zone
based on its course and speed, or (3) the mitigation zone has been
clear from any additional sightings for a period of 10 minutes.
Passive acoustic monitoring will also be conducted with Navy
assets, such as sonobuoys, already participating in the activity. These
assets would only detect vocalizing marine mammals within the frequency
bands monitored by Navy personnel. Passive acoustic detections would
not provide range or bearing to detected animals, and therefore cannot
provide locations of these animals. Passive acoustic detections would
be reported to Lookouts posted in aircraft in order to increase
vigilance of their visual surveillance.

Gunnery Exercises--Small- and Medium-Caliber Using a Surface Target

The Navy is proposing to (1) continue implementing the current
mitigation measures for this activity, (2) clarify the conditions
needed to recommence an activity after a sighting, and (3) add a
requirement to visually observe for kelp paddies.
Mitigation will include visual observation from a vessel or
aircraft immediately before and during the exercise within a mitigation
zone of 200 yd. (183 m) around the intended impact location. Vessels
will observe the mitigation zone from the firing position. When
aircraft are firing, the aircrew will maintain visual watch of the
mitigation zone during the activity. The exercise will not commence if
concentrations of floating vegetation (kelp paddies) are observed in
the mitigation zone. Firing will cease if a marine mammal is sighted
within the mitigation zone. Firing will recommence if any one of the
following conditions is met: (1) The animal is observed exiting the
mitigation zone, (2) the animal is thought to have exited the
mitigation zone based on its course and speed, (3) the mitigation zone
has been clear from any additional sightings for a period of 10 minutes
for a firing aircraft, (4) the mitigation zone has been clear from any
additional sightings for a period of 30 minutes for a firing ship, or
(5) the intended target location has been repositioned more than 400
yd. (366 m) away from the location of the last sighting.

Gunnery Exercises--Large-Caliber Explosive Rounds Using a Surface
Target

The Navy is proposing to (1) continue using the currently
implemented mitigation zone measures for this activity, (2) clarify the
conditions needed to recommence an activity after a sighting, and (3)
implement a requirement to visually observe for kelp paddies. The
recommended measures are provided below.
Mitigation will include visual observation from a ship immediately
before and during the exercise within a mitigation zone of 600 yd. (549
m) around the intended impact location. Ships will observe the
mitigation zone

[[Page 9983]]

from the firing position. The exercise will not commence if
concentrations of floating vegetation (kelp paddies) are observed in
the mitigation zone. Firing will cease if a marine mammal is sighted
within the mitigation zone. Firing will recommence if any one of the
following conditions is met: (1) The animal is observed exiting the
mitigation zone, (2) the animal is thought to have exited the
mitigation zone based on its course and speed, or (3) the mitigation
zone has been clear from any additional sightings for a period of 30
minutes.

Missile Exercises Up to 250 Pound Net Explosive Weight Using a Surface
Target

Currently, the Navy employs a mitigation zone of 1,800 yd. (1.6 km)
for all missile exercises. Because missiles have a wide range of
warhead strength, the Navy is recommending two mitigation zones; one
for missiles with warheads 250 lb. NEW and less, and a larger
mitigation zone for missiles with larger warheads. The Navy is
proposing to (1) modify the mitigation measures currently implemented
for missile exercises involving missiles with 250 lb. NEW and smaller
warheads by reducing the mitigation zone from 1,800 yd. (1.6 km) to 900
yd. (823 m). This new, reduced mitigation zone is a result of the most
recent acoustic propogation modeling efforts (NAEMO) for the GOA TMAA
and is based on a range to effect that is smaller than previously
modeled for missile exercises using a surface target (as discussed
below, the Navy is proposing to increase the mitigation zone for
missiles with a NEW >250 lb.), (2) clarify the conditions needed to
recommence an activity after a sighting, and (3) adopt the marine
mammal mitigation zone size for floating vegetation for ease of
implementation. The recommended measures are provided below.
When aircraft are involved in the missile firing, mitigation will
include visual observation by the aircrew or supporting aircraft prior
to commencement of the activity within a mitigation zone of 900 yd.
(823 m) around the deployed target. The exercise will not commence if
concentrations of floating vegetation (kelp paddies) are observed in
the mitigation zone. Firing will cease if a marine mammal is sighted
within the mitigation zone. Firing will recommence if any one of the
following conditions is met: (1) The animal is observed exiting the
mitigation zone, (2) the animal is thought to have exited the
mitigation zone based on its course and speed, or (3) the mitigation
zone has been clear from any additional sightings for a period of 10
minutes or 30 minutes (depending on aircraft type).

Missile Exercises 251-500 Pound Net Explosive Weight (Surface Target)

Current mitigation measures apply to all missile exercises,
regardless of the warhead size. The Navy proposes to add a mitigation
zone that applies only to missiles with a NEW of 251 to 500 lb. The
recommended measures are provided below.
When aircraft are involved in the missile firing, mitigation will
include visual observation by the aircrew prior to commencement of the
activity within a mitigation zone of 2,000 yd. (1.8 km) around the
intended impact location. The exercise will not commence if
concentrations of floating vegetation (kelp paddies) are observed in
the mitigation zone. Firing will cease if a marine mammal is sighted
within the mitigation zone. Firing will recommence if any one of the
following conditions is met: (1) The animal is observed exiting the
mitigation zone, (2) the animal is thought to have exited the
mitigation zone based on its course and speed, or (3) the mitigation
zone has been clear from any additional sightings for a period of 10
minutes or 30 minutes (depending on aircraft type).

Bombing Exercises

Currently, the Navy employs the following mitigation zone
procedures during bombing exercises:
Ordnance shall not be targeted to impact within 1,000 yd.
(914 m) of known or observed floating kelp or marine mammals.
A 1,000 yd. (914 m) radius mitigation zone shall be
established around the intended target.
The exercise will be conducted only if marine mammals are
not visible within the mitigation zone.
The Navy is proposing to (1) maintain the existing mitigation zone
to be used for non-explosive bombing activities, (2) revise the
mitigation zone procedures to account for predicted ranges to impacts
to marine species when high explosive bombs are used, (3) clarify the
conditions needed to recommence an activity after a sighting, and (4)
add a requirement to visually observe for kelp paddies.
Mitigation will include visual observation from the aircraft
immediately before the exercise and during target approach within a
mitigation zone of 2,500 yd. (2.3 km) around the intended impact
location for explosive bombs and 1,000 yd. (920 m) for non-explosive
bombs. The exercise will not commence if concentrations of floating
vegetation (kelp paddies) are observed in the mitigation zone. Bombing
will cease if a marine mammal is sighted within the mitigation zone.
Bombing will recommence if any one of the following conditions is met:
(1) The animal is observed exiting the mitigation zone, (2) the animal
is thought to have exited the mitigation zone based on its course and
speed, or (3) the mitigation zone has been clear from any additional
sightings for a period of 10 minutes.

Sinking Exercises

The Navy is proposing to (1) modify the mitigation measures
currently implemented for this activity by increasing the mitigation
zone from 2.0 nm to 2.5 nm, (2) clarify the conditions needed to
recommence an activity after a sighting, (3) add a requirement to
visually observe for kelp paddies, and (4) adopt the marine mammal and
sea turtle mitigation zone size for concentrations of floating
vegetation and aggregations of jellyfish for ease of implementation.
The recommended measures are provided below.
Mitigation will include visual observation within a mitigation zone
of 2.5 nm around the target ship hulk. Sinking exercises will include
aerial observation beginning 90 minutes before the first firing, visual
observations from vessels throughout the duration of the exercise, and
both aerial and vessel observation immediately after any planned or
unplanned breaks in weapons firing of longer than 2 hours. Prior to
conducting the exercise, the Navy will review remotely sensed sea
surface temperature and sea surface height maps to aid in deciding
where to release the target ship hulk.
The Navy will also monitor using passive acoustics during the
exercise. Passive acoustic monitoring would be conducted with Navy
assets, such as passive ships sonar systems or sonobuoys, already
participating in the activity. These assets would only detect
vocalizing marine mammals within the frequency bands monitored by Navy
personnel. Passive acoustic detections would not provide range or
bearing to detected animals, and therefore cannot provide locations of
these animals. Passive acoustic detections would be reported to
Lookouts posted in aircraft and on vessels in order to increase
vigilance of their visual surveillance. Lookouts will also increase
observation vigilance before the use of torpedoes or unguided ordnance
with a NEW of 500 lb. or greater, or if the Beaufort sea state is a 4
or above.
The exercise will not commence if concentrations of floating
vegetation (kelp paddies) are observed in the

[[Page 9984]]

mitigation zone. The exercise will cease if a marine mammal, sea
turtle, or aggregation of jellyfish is sighted within the mitigation
zone. The exercise will recommence if any one of the following
conditions is met: (1) The animal is observed exiting the mitigation
zone, (2) the animal is thought to have exited the mitigation zone
based on a determination of its course and speed and the relative
motion between the animal and the source, or (3) the mitigation zone
has been clear from any additional sightings for a period of 30
minutes. Upon sinking the vessel, the Navy will conduct post-exercise
visual surveillance of the mitigation zone for 2 hours (or until
sunset, whichever comes first).

Weapons Firing Noise During Gunnery Exercises--Large-Caliber

The Navy currently has no mitigation zone procedures for this
activity in the Study Area.
The Navy is proposing to adopt measures currently used during Navy
gunnery exercises in other ranges outside of the Study Area. For all
explosive and non-explosive large-caliber gunnery exercises conducted
from a ship, mitigation will include visual observation immediately
before and during the exercise within a mitigation zone of 70 yd. (46
m) within 30 degrees on either side of the gun target line on the
firing side. The exercise will not commence if concentrations of
floating vegetation (kelp paddies) are observed in the mitigation zone.
Firing will cease if a marine mammal is sighted within the mitigation
zone. Firing will recommence if any one of the following conditions is
met: (1) The animal is observed exiting the mitigation zone, (2) the
animal is thought to have exited the mitigation zone based on its
course and speed, (3) the mitigation zone has been clear from any
additional sightings for a period of 30 minutes, or (4) the vessel has
repositioned itself more than 140 yd. (128 m) away from the location of
the last sighting.
Physical Disturbance and Strike

Vessels

The Navy's current measures to mitigate potential impacts to marine
mammals from vessel and in-water device strikes during training
activities are provided below:
Naval vessels shall maneuver to keep at least 500 yd. (457
m) away from any observed whale in the vessel's path and avoid
approaching whales head-on. These requirements do not apply if a
vessel's safety is threatened, such as when change of course will
create an imminent and serious threat to a person, vessel, or aircraft,
and to the extent vessels are restricted in their ability to maneuver.
Restricted maneuverability includes, but is not limited to, situations
when vessels are engaged in dredging, submerged activities, launching
and recovering aircraft or landing craft, minesweeping activities,
replenishment while underway and towing activities that severely
restrict a vessel's ability to deviate course.
Vessels will take reasonable steps to alert other vessels
in the vicinity of the whale. Given rapid swimming speeds and
maneuverability of many dolphin species, naval vessels would maintain
normal course and speed on sighting dolphins unless some condition
indicated a need for the vessel to maneuver.

The Navy is proposing to continue to use the 500 yd. (457 m) mitigation
zone currently established for whales, and to implement a 200 yd. (183
m) mitigation zone for all other marine mammals. Vessels will avoid
approaching marine mammals head on and will maneuver to maintain a
mitigation zone of 500 yd. (457 m) around observed whales and 200 yd.
(183 m) around all other marine mammals (except bow-riding dolphins),
providing it is safe to do so. The Navy is clarifying its existing
speed protocol; while in transit, Navy vessels shall be alert at all
times, use extreme caution, and proceed at a ``safe speed'' so that the
vessel can take proper and effective action to avoid a collision with
any sighted object or disturbance, including any marine mammal or sea
turtle, and can be stopped within a distance appropriate to the
prevailing circumstances and conditions.

Towed In-Water Devices

The Navy currently has no mitigation zone procedures for this
activity in the Study Area.
The Navy is proposing to adopt measures currently used in other
ranges outside of the Study Area during activities involving towed in-
water devices. The Navy will ensure that towed in-water devices being
towed from manned platforms avoid coming within a mitigation zone of
250 yd. (229 m) around any observed marine mammal, providing it is safe
to do so.
Non-Explosive Practice Munitions

Gunnery Exercises--Small-, Medium-, and Large-Caliber Using a Surface
Target

Currently, the Navy employs the same mitigation measures for non-
explosive gunnery exercises as described above for Gunnery Exercises--
Small-, Medium-, and Large-Caliber Using a Surface Target.
The Navy is proposing to (1) continue using the mitigation measures
currently implemented for this activity, and (2) clarify the conditions
needed to recommence an activity after a sighting. The recommended
measures are provided below.
Mitigation will include visual observation from a vessel or
aircraft immediately before and during the exercise within a mitigation
zone of 200 yd. (183 m) around the intended impact location. The
exercise will not commence if concentrations of floating vegetation
(kelp paddies) are observed in the mitigation zone. Firing will cease
if a marine mammal is sighted within the mitigation zone. Firing will
recommence if any one of the following conditions is met: (1) The
animal is observed exiting the mitigation zone, (2) the animal is
thought to have exited the mitigation zone based on its course and
speed, (3) the mitigation zone has been clear from any additional
sightings for a period of 10 minutes for a firing aircraft, (4) the
mitigation zone has been clear from any additional sightings for a
period of 30 minutes for a firing ship, or (5) the intended target
location has been repositioned more than 400 yd. (366 m) away from the
location of the last sighting.

Bombing Exercises

The Navy is proposing to continue using the mitigation measures
currently implemented for this activity. The recommended measure
includes clarification of a post-sighting activity recommencement
criterion.
Mitigation will include visual observation from the aircraft
immediately before the exercise and during target approach within a
mitigation zone of 1,000 yd. (914 m) around the intended impact
location. The exercise will not commence if concentrations of floating
vegetation (kelp paddies) are observed in the mitigation zone. Bombing
will cease if a marine mammal is sighted within the mitigation zone.
Bombing will recommence if any one of the following conditions is met:
(1) The animal is observed exiting the mitigation zone, (2) the animal
is thought to have exited the mitigation zone based on its course and
speed, or (3) the mitigation zone has been clear from any additional
sightings for a period of 10 minutes.

Missile Exercises (Including Rockets) Using a Surface Target

The Navy is proposing to (1) modify the mitigation measures
currently

[[Page 9985]]

implemented for this activity by reducing the mitigation zone from
1,800 yd. (1.6 km) to 900 yd. (823 m), (2) clarify the conditions
needed to recommence an activity after a sighting, (3) adopt the marine
mammal and sea turtle mitigation zone size for floating vegetation for
ease of implementation, and (4) modify the platform of observation to
eliminate the requirement to observe when ships are firing. The
recommended measures are provided below.
When aircraft are firing, mitigation will include visual
observation by the aircrew or supporting aircraft prior to commencement
of the activity within a mitigation zone of 900 yd. (823 m) around the
deployed target. The exercise will not commence if concentrations of
floating vegetation (kelp paddies) are observed in the mitigation zone.
Firing will cease if a marine mammal is sighted within the mitigation
zone. Firing will recommence if any one of the following conditions is
met: (1) The animal is observed exiting the mitigation zone, (2) the
animal is thought to have exited the mitigation zone based on a
determination of its course and speed and the relative motion between
the animal and the source, or (3) the mitigation zone has been clear
from any additional sightings for a period of 10 minutes or 30 minutes
(depending on aircraft type).

Consideration of Time/Area Limitations

The Navy's and NMFS' analysis of effects to marine mammals
considers emergent science regarding locations where cetaceans are
known to engage in specific activities (e.g., feeding, breeding/
calving, or migration) at certain times of the year that are important
to individual animals as well as populations of marine mammals (see
discussion in Van Parijs, 2015). Where data were available, Van Parijs
(2015) identified areas that are important in this way and named the
areas Biologically Important Areas (BIAs). It is important to note that
the BIAs were not meant to define exclusionary zones, nor were they
meant to be locations that serve as sanctuaries from human activity, or
areas analogous to marine protected areas (see Ferguson et al. (2015a)
regarding the envisioned purpose for the BIA designations). The
delineation of BIAs does not have direct or immediate regulatory
consequences, although it is appropriate to consider them as part of
the body of science that may inform mitigation decisions, depending on
the circumstances. The intention was that the BIAs would serve as
resource management tools and that they be considered along with any
new information as well as, ``existing density estimates, range-wide
distribution data, information on population trends and life history
parameters, known threats to the population, and other relevant
information'' (Van Parijs, 2015).
The Navy and NMFS have supported and will continue to support the
Cetacean and Sound Mapping project, including representation on the
Cetacean Density and distribution Working Group (CetMap), which
informed NMFS' identification of BIAs. The same marine mammal density
data present in the Navy's Marine Species Density Database Technical
Report (U.S. Department of the Navy, 2014) and used in the analysis for
the GOA SEIS/OEIS was used in the development of BIAs. The final
products, including the Gulf of Alaska BIAs, from this mapping effort
were completed and published in March 2015 (Aquatic Mammals, 2015;
Calambokidis et al., 2015; Ferguson et al., 2015a, 2015b; Van Parijs,
2015). 131 BIAs for 24 marine mammal species, stocks, or populations in
seven regions within U.S. waters were identified (Ferguson et al.,
2015a). BIAs have been identified in the Gulf of Alaska in the vicinity
of the GOA TMAA Study Area and include migratory and feeding BIAs for
gray whale and North Pacific right whale, respectively. However, the
degree of overlap between these BIAs and the Study area is negligible
geographically. NMFS' recognition of an area as biologically important
for some species activity is not equivalent to designation of critical
habitat under the Endangered Species Act. Furthermore, the BIAs
identified by NMFS in and around the Study Area do not represent the
totality of important habitat throughout the marine mammals' full
range.
NMFS' Office of Protected Resources routinely considers available
information about marine mammal habitat use to inform discussions with
applicants regarding potential spatio-temporal limitations on their
activities that might help effect the least practicable adverse impact
on species or stocks and their habitat. BIAs are useful tools for
planning and impact assessments and are being provided to the public
via this Web site: www.cetsound.noaa.gov. While these BIAs are useful
tools for analysts, any decisions regarding protective measures based
on these areas must go through the normal MMPA evaluation process (or
any other statutory process that the BIAs are used to inform); the
identification of a BIA does not pre-suppose any specific management
decision associated with those areas, nor does it have direct or
immediate regulatory consequences. NMFS and the Navy have discussed the
BIAs listed above, what Navy activities take place in these areas (in
the context of what their effects on marine mammals might be or whether
additional mitigation is necessary), and what measures could be
implemented to reduce impacts in these areas (in the context of their
potential to reduce marine mammal impacts and their practicability). An
assessment of the potential spatio-temporal and activity overlap of
Navy training activities with the Gulf of Alaska BIAs listed above is
included below and in Chapter 3.8 of the GOA DSEIS/OEIS. In addition,
in the Group and Species-Specific Analysis section of this proposed
rule NMFS has preliminarily assessed the potential effects of Navy
training on the ability of gray whale and North Pacific right whale to
engage in those activities for which the BIAs have been identified
(migratory and feeding). As we learn more about marine mammal density,
distribution, and habitat use (and the BIAs are updated), NMFS and the
Navy will continue to reevaluate appropriate time-area measures through
the Adaptive Management process outlined in these regulations.
North Pacific Right Whale Feeding Area--The NMFS-identified feeding
area for North Pacific right whales (see Ferguson et al., 2015b)
overlaps slightly with the GOA TMAA's southwestern corner. This feeding
area is applicable from June to September so there is temporal overlap
with the proposed Navy training but there is minimal (<1 percent)
spatial overlap between this feeding area and the GOA TMAA (see Figure
3.8-2 of the GOA DSEIS/OEIS).
Given their current extremely low population numbers and the
general lack of sightings in the Gulf of Alaska, the occurrence of
right whales in the GOA TMAA is considered rare. North Pacific right
whales have not been visually detected in the GOA TMAA since at least
the 1960s. The Quinn Seamount passive acoustic detections in summer
2013 ([Scaron]irovi[cacute] et al., 2014) are the only known potential
occurrence records of this species in the GOA TMAA in recent years.
Grey Whale Migratory Area--The NMFS-identified migration area for
gray whales, which was bounded by the extent of the continental shelf
(as provided in Ferguson et al., 2015b), has slight (<1 percent)
overlap with the GOA TMAA at its northernmost corner and western edge
(see Ferguson et al., 2015b; See Figure 3.8-4 of the GOA DSEIS/OEIS).
However, this migration area is applicable only between March to May
(Spring) and November to

[[Page 9986]]

January (Fall) (see Aquatic Mammals, 2015). This NMFS-identified gray
whale migration area would not be applicable during the months when
training has historically occurred (June/July) and is not likely to
have temporal overlap with most of the proposed timeframe (May to
October; summer) for Navy training in the GOA TMAA. It is worth
mentioning that the Navy's acoustic analysis did not predict any takes
of gray whales in the GOA TMAA and NMFS is not authorizing any takes of
this species (see Group and Species-Specific Analysis section later in
this proposed rule).
Potential Training Overlap with BIAs--It is very unlikely that Navy
training would occur in these nearshore locations adjacent to the GOA
TMAA boundary where the overlap with BIAs occurs. To ensure that the
Navy is able to conduct realistic training, Navy units must maintain
sufficient room to maneuver. Therefore, training activities will
typically take place some distance away from an operating area boundary
to ensure sufficient sea or air space is available for tactical
maneuvers within an approved operating area such as the GOA TMAA. The
Navy also does not typically train next to any limiting boundary
because it precludes tactical consideration of the adjacent sea space
and airspace beyond the boundary from being a potential threat axis
during activities such as anti-submarine warfare training. It is also
the case that Navy training activities will generally not be located
where it is likely there would be interference from civilian vessels
and aircraft that are not participating in the training activity. The
nearshore boundary of the GOA TMAA is the location for multiple
commercial vessel transit lanes, ship traffic, and low-altitude air
routes, which all pass through the NMFS-identified feeding area and the
identified migration area (see Figure 3.8-9 of the GOA DSEIS/OEIS).
This level of civilian activity may otherwise conflict with Navy
training activities if those Navy activities were located at that
margin of the GOA TMAA and as a result such an area is generally
avoided.
In short, the corners of and edge of the GOA TMAA are seldom if
ever a suitable location for sustained, realistic, and coordinated
training using sonar and other active acoustic sources or explosives.
The Navy has lookouts and mitigation measures in place to maneuver away
from and around marine mammals, and Navy vessels and aircraft are no
more likely to cause any impact to these species than any other non-
Navy vessels or aircraft in the area. The Navy's stand-off distance for
vessels of 500 yd. (457 m) and mitigation procedures (see Proposed
Mitigation) further reduce the potential that there would be any
biologically meaningful effect to feeding or migration should animals
be present and detected during a very unlikely Navy training event
using sonar and other active acoustic sources or explosives in one of
these overlapping NMFS-identified areas. Therefore, North Pacific right
whales and gray whales in the NMFS-identified feeding or migration
areas at these boundaries of the GOA TMAA are very unlikely to have
their feeding or migration activities affected by Navy training
activities using sonar and other active acoustic sources.
Conclusion--Based on the likely locations for training in the GOA
TMAA, the Navy and NMFS anticipate that proposed training activities
would have very limited, if any, spatial or temporal overlap with the
designated North Pacific right whale area or gray whale biologically
important areas. Therefore, it is unlikely that Navy training would
have any biologically meaningful effect on North Pacific right whale
feeding behavior or gray whale migration behavior in these areas.
Moreover, appropriate mitigation measures (as detailed in Proposed
Mitigation above) would be implemented for any detected marine mammals
and thus further reduce the potential for the feeding or migration
activities to be affected.

Stranding Response Plan

NMFS and the Navy developed a Stranding Response Plan for GOA TMAA
in 2011 as part of the previous (2011-2016) incidental take
authorization and rulemaking process for the Study Area. The Stranding
Response Plan is specifically intended to outline the applicable
requirements in the event that a marine mammal stranding is reported in
the complexes during a major training exercise. NMFS considers all
plausible causes within the course of a stranding investigation and
this plan in no way presumes that any strandings are related to, or
caused by, Navy training activities, absent a determination made during
investigation. The plan is designed to address mitigation, monitoring,
and compliance. The current Stranding Response Plan for the GOA TMAA is
available for review at: http://www.nmfs.noaa.gov/pr/permits/goa_tmaa_stranding_protocol.pdf. NMFS and the Navy are currently
updating the Stranding Response Plan for the GOA TMAA for 2016-2021
training activities. The updated Stranding Response Plan will be
finalized prior to the release of the final rule, and will be made
available for review at: http://www.nmfs.noaa.gov/pr/permits/incidental/military.htm#navy_goa2021. In addition, modifications to the
Stranding Response Plan may also be made through the adaptive
management process.

Mitigation Conclusions

NMFS has carefully evaluated the Navy's proposed mitigation
measures--many of which were developed with NMFS' input during the
first phase of Navy Training authorizations--and considered a broad
range of other measures in the context of ensuring that NMFS prescribes
the means of effecting the least practicable adverse impact on the
affected marine mammal species and stocks and their habitat. Our
evaluation of potential measures included consideration of the
following factors in relation to one another: The manner in which, and
the degree to which, the successful implementation of the mitigation
measures is expected to reduce the likelihood and/or magnitude of
adverse impacts to marine mammal species and stocks and their habitat;
the proven or likely efficacy of the measures; and the practicability
of the suite of measures for applicant implementation, including
consideration of personnel safety, practicality of implementation, and
impact on the effectiveness of the military readiness activity.
Based on our evaluation of the Navy's proposed measures, as well as
other measures considered by NMFS, NMFS has determined preliminarily
that the Navy's proposed mitigation measures (especially when the
adaptive management component is taken into consideration (see Adaptive
Management, below)) are adequate means of effecting the least
practicable adverse impacts on marine mammals species or stocks and
their habitat, paying particular attention to rookeries, mating
grounds, and areas of similar significance, while also considering
personnel safety, practicality of implementation, and impact on the
effectiveness of the military readiness activity.
The proposed rule comment period provides the public an opportunity
to submit recommendations, views, and/or concerns regarding this action
and the proposed mitigation measures. While NMFS has determined
preliminarily that the Navy's proposed mitigation measures would affect
the least practicable adverse impact on the affected species or stocks
and their habitat, NMFS will consider all public comments to help
inform our final

[[Page 9987]]

decision. Consequently, the proposed mitigation measures may be
refined, modified, removed, or added to prior to the issuance of the
final rule based on public comments received, and where appropriate,
further analysis of any additional mitigation measures.

Proposed Monitoring

Section 101(a)(5)(A) of the MMPA states that in order to issue an
ITA for an activity, NMFS must set forth ``requirements pertaining to
the monitoring and reporting of such taking''. The MMPA implementing
regulations at 50 CFR 216.104 (a)(13) indicate that requests for LOAs
must include the suggested means of accomplishing the necessary
monitoring and reporting that will result in increased knowledge of the
species and of the level of taking or impacts on populations of marine
mammals that are expected to be present.

Integrated Comprehensive Monitoring Program (ICMP)

The Navy's ICMP is intended to coordinate monitoring efforts across
all regions and to allocate the most appropriate level and type of
effort for each range complex based on a set of standardized
objectives, and in acknowledgement of regional expertise and resource
availability. The ICMP is designed to be a flexible, scalable, and
adaptable through the adaptive management and strategic planning
processes to periodically assess progress and reevaluate objectives.
Although the ICMP does not specify actual monitoring field work or
projects, it does establish top-level goals that have been developed in
coordination with NMFS. As the ICMP is implemented, detailed and
specific studies will be developed which support the Navy's top-level
monitoring goals. In essence, the ICMP directs that monitoring
activities relating to the effects of Navy training and testing
activities on marine species should be designed to contribute towards
one or more of the following top-level goals:
An increase in our understanding of the likely occurrence
of marine mammals and/or ESA-listed marine species in the vicinity of
the action (i.e., presence, abundance, distribution, and/or density of
species);
An increase in our understanding of the nature, scope, or
context of the likely exposure of marine mammals and/or ESA-listed
species to any of the potential stressor(s) associated with the action
(e.g., tonal and impulsive sound), through better understanding of one
or more of the following: (1) The action and the environment in which
it occurs (e.g., sound source characterization, propagation, and
ambient noise levels); (2) the affected species (e.g., life history or
dive patterns); (3) the likely co-occurrence of marine mammals and/or
ESA-listed marine species with the action (in whole or part) associated
with specific adverse effects, and/or; (4) the likely biological or
behavioral context of exposure to the stressor for the marine mammal
and/or ESA-listed marine species (e.g., age class of exposed animals or
known pupping, calving or feeding areas);
An increase in our understanding of how individual marine
mammals or ESA-listed marine species respond (behaviorally or
physiologically) to the specific stressors associated with the action
(in specific contexts, where possible, e.g., at what distance or
received level);
An increase in our understanding of how anticipated
individual responses, to individual stressors or anticipated
combinations of stressors, may impact either: (1) The long-term fitness
and survival of an individual; or (2) the population, species, or stock
(e.g., through effects on annual rates of recruitment or survival);
An increase in our understanding of the effectiveness of
mitigation and monitoring measures;
A better understanding and record of the manner in which
the authorized entity complies with the ITA and Incidental Take
Statement;
An increase in the probability of detecting marine mammals
(through improved technology or methods), both specifically within the
safety zone (thus allowing for more effective implementation of the
mitigation) and in general, to better achieve the above goals; and
A reduction in the adverse impact of activities to the
least practicable level, as defined in the MMPA.
Monitoring would address the ICMP top-level goals through a
collection of specific regional and ocean basin studies based on
scientific objectives. Quantitative metrics of monitoring effort (e.g.,
20 days of aerial surveys) would not be a specific requirement. The
adaptive management process and reporting requirements would serve as
the basis for evaluating performance and compliance, primarily
considering the quality of the work and results produced, as well as
peer review and publications, and public dissemination of information,
reports, and data. Details of the ICMP are available online (http://www.navymarinespeciesmonitoring. us/).

Strategic Planning Process for Marine Species Monitoring

The Navy also developed the Strategic Planning Process for Marine
Species Monitoring, which establishes the guidelines and processes
necessary to develop, evaluate, and fund individual projects based on
objective scientific study questions. The process uses an underlying
framework designed around top-level goals, a conceptual framework
incorporating a progression of knowledge, and in consultation with a
Scientific Advisory Group and other regional experts. The Strategic
Planning Process for Marine Species Monitoring would be used to set
intermediate scientific objectives, identify potential species of
interest at a regional scale, and evaluate and select specific
monitoring projects to fund or continue supporting for a given fiscal
year. This process would also address relative investments to different
range complexes based on goals across all range complexes, and
monitoring would leverage multiple techniques for data acquisition and
analysis whenever possible. The Strategic Planning Process for Marine
Species Monitoring is also available online (http://www.navymarinespeciesmonitoring navymarinespeciesmonitoring.us/).

Past and Current Monitoring in the Study Area

NMFS has received multiple years' worth of annual exercise and
monitoring reports addressing active sonar use and explosive
detonations within the GOA TMAA and other Navy range complexes. The
data and information contained in these reports have been considered in
developing mitigation and monitoring measures for the proposed training
activities within the Study Area. The Navy's annual exercise and
monitoring reports may be viewed at: http://www.nmfs.noaa.gov/pr/permits/incidental/military.htm and http://www.navymarinespeciesmonitoring.us. NMFS has reviewed these reports and
summarized the results, as related to marine mammal monitoring, below.
1. The Navy has shown significant initiative in developing its
marine species monitoring program and made considerable progress toward
reaching goals and objectives of the ICMP.
2. Observation data from watchstanders aboard navy vessels is
generally useful to indicate the presence or absence of marine mammals
within the mitigation zones (and sometimes beyond) and to document the
implementation of mitigation measures, but does not provide useful
species-specific information or behavioral data.

[[Page 9988]]

3. Data gathered by experienced marine mammal observers can provide
very valuable information at a level of detail not possible with
watchstanders.
4. Though it is by no means conclusive, it is worth noting that no
instances of obvious behavioral disturbance have been observed by Navy
watchstanders or experienced marine mammal observers conducting visual
monitoring.
5. Visual surveys generally provide suitable data for addressing
questions of distribution and abundance of marine mammals, but are much
less effective at providing information on movements and behavior, with
a few notable exceptions where sightings are most frequent.
6. Passive acoustics and animal tagging have significant potential
for applications addressing animal movements and behavioral response to
Navy training activities, but require a longer time horizon and heavy
investment in analysis to produce relevant results.
7. NMFS and the Navy should more carefully consider what and how
information should be gathered by watchstanders during training
exercises and monitoring events, as some reports contain different
information, making cross-report comparisons difficult.
This section is a summary of Navy-funded compliance monitoring in
the GOA TMAA since 2011. Additional Navy-funded monitoring outside of
and in addition to the Navy's commitments to NMFS is provided later in
this section.
Gulf of Alaska Study Area Monitoring, 2011-2015--During the LOA
development process for the 2011 GOA FEIS/OEIS, the Navy and NMFS
agreed that monitoring in the Gulf of Alaska should focus on augmenting
existing baseline data, since regional data on species occurrence and
density are extremely limited. There have been four reports to date
covering work in the Gulf of Alaska (U.S. Department of the Navy,
2011c, 2011d, 2012, 2013f). Collecting baseline data was deemed a
priority prior to focusing on exercise monitoring and behavioral
response as is now being done in other Navy OPAREAs and ranges. There
have been no previous dedicated monitoring efforts during Navy training
activities in the GOA TMAA with the exception of deployed HARPs.
In July 2011, the Navy funded deployment of two long-term bottom-
mounted passive acoustic monitoring buoys by Scripps Institute of
Oceanography. These HARPs were deployed southeast of Kenai Peninsula in
the GOA TMAA with one on the shelf approximately 50 nm from land (in
111 fathoms [203 m] depth) and on the shelf-break slope approximately
100 nm from land (in 492 fathoms [900 m] depth). Intended to be
collected annually, results from the first deployment (July 2011-May
2012) included over 5,756 hours of passive acoustic data (Baumann-
Pickering et al. 2012b). Identification of marine mammal sounds
included four baleen whale species (blue whales, fin whales, gray
whales, and humpback whales) and at least six species of odontocetes
(killer whale, sperm whale, Stejneger's beaked whale, Baird's beaked
whale, Cuvier's beaked whale, and an unidentified porpoise presumed to
be Dall's porpoise; Baumann-Pickering et al., 2012b). Researchers also
noted the detection of anthropogenic sound from commercial shipping.
There were no Navy activities or vessels in the area at any time during
the recording period.
Analysis of the passive acoustic detections made from May 2012 to
June 2013 were presented in Baumann-Pickering et al. (2013), Debich et
al. (2013), Debich et al. (2014), and the Navy's 2012, 2013, and 2014
GOA TMAA annual monitoring report submitted to NMFS (U.S. Department of
the Navy, 2012, 2013f, 2014d). Three baleen whale species were
detected: Blue whales, fin whales, and humpback whales. No North
Pacific right whale calls were detected at either site during this
monitoring period. At least seven species of odontocetes were detected:
Risso's dolphins, killer whales, sperm whales, Baird's beaked whales,
Cuvier's beaked whales, Stejneger's beaked whales, and unidentified
porpoises (likely Dall's porpoise). Focused analysis of beaked whale
echolocation recordings were presented in Baumann-Pickering et al.
(2013).
As also presented in Debich et al. (2013) and U.S. Department of
the Navy (2013f), broadband ship noise was found to be more common at
the slope and Pratt Seamount monitoring sites within the GOA TMAA than
at the nearshore (on shelf) site. Sonar (a variety of frequencies, most
likely fathometers and fish-finders), were more common on the shelf and
slope sites. Very few explosions were recorded at any of the three
sites throughout the monitoring period. Origin of the few explosions
detected are unknown, but there was no Navy explosive use in the GOA
TMAA during this period, so these explosive-like events may be related
to fisheries activity, lightning strikes, or some other unidentified
source. There were no detections of Navy mid-frequency sonar use in the
recordings (Debich et al. 2013, 2014; U.S. Department of the Navy
2013f, 2014d). In September 2012, an additional HARP buoy was deployed
at Pratt Seamount (near the east end of the GOA TMAA) and in June 2013
two additional buoys were deployed in the GOA TMAA: One at the shelf-
break near the southwest corner of the GOA TMAA and one at Quinn
Seamount (the approximate middle of the GOA TMAA's southeast boundary).
This constitutes a total of five Navy-funded concurrent long-term
passive acoustic monitoring packages present in the GOA TMAA through
fall of 2014. Debich et al. (2013) reported the first detection of a
North Pacific right whale at the Quinn Seamount site. Over two days
between June and August 2013, the Quinn seamount HARP detected three
hours of North Pacific right whale calls (Debich et al., 2014,
[Scaron]irovi[cacute] et al., in press). Given the recording device
location near the southwest border of the GOA TMAA, inability of the
device as configured to determine call directionality, and likely
signal propagation of several 10s of miles, it remains uncertain if the
detected calls orginated within or outside of the GOA TMAA. Previous
related Navy funded monitoring at multiple sites within the Study Area
reported no North Pacific right whale detections (Baumann-Pickering et
al., 2012b, Debich et al., 2013). Additional monitoring conducted in
the GOA TMAA through spring 2015 included the deployment of five HARPs
to detect marine mammals and anthropogenic sounds (Rice et al., 2015).
Future monitoring will include varying numbers of HARPs or other
passive acoustic technologies based on annual Adaptive Management
discussions with NMFS (see U.S. Department of the Navy [2014d] for
details in that regard).
In the Gulf of Alaska, the Navy has also funded two previous marine
mammal surveys to gather occurrence and density data. Although there
was no regulatory requirement for the Navy to undertake either survey,
the Navy funded the data collection to first support analysis of
potential effects for the 2011 GOA FEIS/OEIS and again recently to
support the current SEIS/OEIS. The first Navy-funded survey (GOALS) was
conducted by NMFS in April 2009 (see Rone et al., 2009). Line-transect
survey visual data was gathered to support distance sampling statistics
and acoustic data were collected over a 10-day period both within and
outside the GOA TMAA. This survey resulted in sightings of several
species and allowed for the derivation of densities for fin and
humpback whale that supplemented multiple previous survey efforts in
the

[[Page 9989]]

vicinity (Rone et al., 2009). In summer 2013, the Navy funded an
additional visual line-transect survey in the offshore waters of the
Gulf of Alaska (Rone et al., 2014). The GOALS II survey was a 30-day
visual line-transect survey supplemented by use of passive acoustics
and was a follow-on effort to the previously Navy-funded GOALS survey
in 2009. The primary objectives for the GOALS II survey were to acquire
baseline data to increase understanding of the likely occurrence (i.e.,
presence, abundance, distribution and/or density of species) of beaked
whales and ESA-listed marine mammals in the Gulf of Alaska. Specific
research objectives were:
Assess the abundance, spatial distribution and/or density
of marine mammals, with a focus on beaked whales and ESA-listed
cetacean species through visual line-transect surveys and passive
acoustics using a towed hydrophone array and sonobuoys
Increase knowledge of species' vocal repertoire by linking
visual sightings to vocally active cetaceans, in order to improve the
effectiveness of passive acoustic monitoring
Attempt to photo-identify and biopsy sample individual
whales opportunistically for analysis of population structure, genetics
and habitat use
Attempt to locate whales for opportunistic satellite
tagging using visual and passive acoustic methodology in order to
provide information on both large- and fine-scale movements and habitat
use of cetaceans
The Navy-funded GOALS II survey also sampled four distinct habitat
areas (shelf, slope, offshore, and seamounts) which were partitioned
into four strata. The survey design was intended to provide uniform
coverage within the Gulf of Alaska. However, given the overall limited
knowledge of beaked whales within the Gulf of Alaska, the survey was
also designed to provide coverage of potential beaked whale habitat and
resulted in 13 encounters with beaked whales numbering 67 individual
animals (Rone et al., 2014). The following additional details are
summarized from the presentation in Rone et al. (2014). The visual
survey consisted of 4,504 km (2,431 nm) of `full-effort' and included
349 km (188 nm) of `transit-effort.' There was an additional 375 km
(202 nm) of `fog-effort' (transect and transit). Based on total effort,
there were 802 sightings (1,998 individuals) identified to species,
with an additional 162 sightings (228 individuals) of unidentified
cetaceans and pinnipeds. Acoustic surveying was conducted round-the-
clock with a towed-hydrophone array for 6,304 km (3,997 nm) of line-
transect effort totaling 426 hours of `standard' monitoring, with an
additional 374 km (202 nm) of ~30 hours of `non-standard' and `chase'
effort. There were 379 acoustic detections and 267 localizations of 6
identified cetacean species. Additionally, 186 acoustic sonobuoys were
deployed with 7 identified cetacean species detected. Two satellite
transmitter tags were deployed; a tag on a blue whale (B. musculus)
transmitted for 9 days and a tag on a Baird's beaked whale (Berardius
bairdii) transmitted for 15 days. Based on photo-identification
matches, the tagged blue whale had been previously identified off Baja
California, Mexico, in 2005. Photographs of five cetacean species were
collected for photo-identification purposes: fin, humpback, blue,
killer (Orcinus orca) and Baird's beaked whales. The estimates of
abundance and density for five species were obtained for the first time
for the central Gulf of Alaska. Overall, the Navy funded GOALS II
survey provided one of the most comprehensive datasets on marine mammal
occurrence, abundance, and distribution within that rarely surveyed
area (Rone et al., 2014).
NMFS has acknowledged that the Navy's GOA TMAA monitoring will
enhance understanding of marine mammal vocalizations and distributions
within the offshore waters of the Gulf of Alaska. Additionally, NMFS
pointed out that information gained from the investigations associated
with the Navy's monitoring may be used in the adaptive management of
monitoring measures in subsequent NMFS authorizations, if appropriate
and in consultation with NMFS. The Navy is committed to structuring the
Navy-sponsored research and monitoring program to address both NMFS'
regulatory requirements as part of any MMPA authorizations while at the
same time making significant contributions to the greater body of
marine mammal science (see U.S. Department of the Navy, 2013f).
Pacific Northwest Cetacean Tagging--A Navy-funded effort in the
Pacific Northwest is ongoing and involves attaching long-term satellite
tracking tags to migrating gray whales off the coast of Oregon and
northern California (U.S. Department of the Navy, 2013e). This study is
being conducted by the University of Oregon and has also included
tagging of other large whale species such as humpback whales, fin
whales, and killer whales when encountered. This effort is not
programmed, affiliated, or managed as part of the GOA TMAA monitoring,
and is a separate regional project, but has provided information on
marine mammals and their movements that has application to the Gulf of
Alaska.
In one effort between May 2010 and May 2013, satellite tracking
tags were placed on three gray whales, 11 fin whales, five humpback
whales, and two killer whales off the Washington coast (Schorr et al.,
2013). One tag on an Eastern North Pacific Offshore stock killer whale,
in a pod encountered off Washington at Grays Harbor Canyon, remained
attached and continued to transmit for approximately 3 months. In this
period, the animal transited a distance of approximately 4,700 nm,
which included time spent in the nearshore margins of the TMAA in the
Gulf of Alaska where it would be considered part of the Offshore stock
(for stock designations, see Muto and Angliss, 2015). In a second
effort between 2012 and 2013, tags were attached to 11 Pacific Coast
Feeding Group gray whales near Crescent City, California; in general,
the tag-reported positions indicated these whales were moving southward
at this time of year (Mate, 2013). The Navy's 2013 annual monitoring
report for the Northwest Training and Testing Range contains the
details of the findings from both research efforts described above
(U.S. Department of the Navy, 2013e).

Proposed Monitoring for the GOA TMAA Study Area

Based on NMFS-Navy meetings in June and October 2011, and the
upcoming annual monitoring meeting scheduled for March 2016, future
Navy compliance monitoring, including ongoing monitoring, will address
ICMP top-level goals through a series of regional and ocean basin study
questions with a prioritization and funding focus on species of
interest as identified for each range complex. The ICMP will also
address relative investments to different range complexes based on
goals across all range complexes, and monitoring will leverage multiple
techniques for data acquisition and analysis whenever possible.
Within the GOA TMAA Study Area, the Navy's monitoring for GOA TMAA
under this LOA authorization and concurrently in other areas of the
Pacific Ocean will therefore be structured to address region-specific
species-specific study questions in consultation with NMFS.
The outcome of the March 2016 Navy-NMFS monitoring meeting,
including any proposed monitoring during the period covered by this
proposed rule

[[Page 9990]]

(2016-2021) will be discussed in the final rule. In addition, Navy
monitoring projects proposed during the 2016-2021 GOA TMAA rulemaking
period will be posted on the Navy's marine species monitoring Web site
(http://www.navymarinespeciesmonitoring.us/regions/pacific/current-
projects/).

Ongoing Navy Research

The U.S. Navy is one of the world's leading organizations in
assessing the effects of human activities on the marine environment
including marine mammals. From 2004 through 2013, the Navy has funded
over $240M specifically for marine mammal research. Navy scientists
work cooperatively with other government researchers and scientists,
universities, industry, and non-governmental conservation organizations
in collecting, evaluating, and modeling information on marine
resources. They also develop approaches to ensure that these resources
are minimally impacted by existing and future Navy operations. It is
imperative that the Navy's R&D efforts related to marine mammals are
conducted in an open, transparent manner with validated study needs and
requirements. The goal of the Navy's R&D program is to enable
collection and publication of scientifically valid research as well as
development of techniques and tools for Navy, academic, and commercial
use. Historically, R&D programs are funded and developed by the Navy's
Chief of Naval Operations Energy and Environmental Readiness Division
(OPNAV N45) and Office of Naval Research (ONR), Code 322 Marine Mammals
and Biological Oceanography Program. The primary focus of these
programs since the 1990s is on understanding the effects of sound on
marine mammals, including physiological, behavioral, and ecological
effects.
ONR's current Marine Mammals and Biology Program thrusts include,
but are not limited to: (1) monitoring and detection research, (2)
integrated ecosystem research including sensor and tag development, (3)
effects of sound on marine life (such as hearing, behavioral response
studies, physiology [diving and stress], and PCAD), and (4) models and
databases for environmental compliance.
To manage some of the Navy's marine mammal research programmatic
elements, OPNAV N45 developed in 2011 a new Living Marine Resources
(LMR) Research and Development Program (http://www.lmr.navy.mil/). The
goal of the LMR Research and Development Program is to identify and
fill knowledge gaps and to demonstrate, validate, and integrate new
processes and technologies to minimize potential effects to marine
mammals and other marine resources. Key elements of the LMR program
include:
Providing science-based information to support Navy
environmental effects assessments for research, development,
acquisition, testing and evaluation as well as Fleet at-sea training,
exercises, maintenance and support activities.
Improving knowledge of the status and trends of marine
species of concern and the ecosystems of which they are a part.
Developing the scientific basis for the criteria and
thresholds to measure the effects of Navy generated sound.
Improving understanding of underwater sound and sound
field characterization unique to assessing the biological consequences
resulting from underwater sound (as opposed to tactical applications of
underwater sound or propagation loss modeling for military
communications or tactical applications).
Developing technologies and methods to monitor and, where
possible, mitigate biologically significant consequences to living
marine resources resulting from naval activities, emphasizing those
consequences that are most likely to be biologically significant.

Navy Research and Development

Navy Funded--Both the LMR and ONR Research and Development Programs
periodically fund projects within the Study Area. Some data and
results, when available from these R&D projects, are typically
summarized in the Navy's annual range complex Monitoring Reports that
are currently submitted to the NMFS each year. In addition, the Navy's
Range Complex monitoring during training and testing activities is
coordinated with the R&D monitoring in a given region to leverage
research objectives, assets, and studies where possible under the ICMP.
The integration between the Navy's new LMR Research and Development
Program and related range complex monitoring will continue and improve
during this LOA application period with applicable results presented in
GOA TMAA annual monitoring reports.
Other National Department of Defense Funded Initiatives--Strategic
Environmental Research and Development Program (SERDP) and
Environmental Security Technology Certification Program (ESTCP) are the
DoD's environmental research programs, harnessing the latest science
and technology to improve environmental performance, reduce costs, and
enhance and sustain mission capabilities. The Programs respond to
environmental technology requirements that are common to all of the
military Services, complementing the Services' research programs. SERDP
and ESTCP promote partnerships and collaboration among academia,
industry, the military Services, and other Federal agencies. They are
independent programs managed from a joint office to coordinate the full
spectrum of efforts, from basic and applied research to field
demonstration and validation.

Adaptive Management

The final regulations governing the take of marine mammals
incidental to Navy training activities in the Study Area would contain
an adaptive management component carried over from previous
authorizations. Although better than 5 years ago, our understanding of
the effects of Navy training and testing activities (e.g., MFAS/HFAS,
underwater detonations) on marine mammals is still relatively limited,
and yet the science in this field is evolving fairly quickly. These
circumstances make the inclusion of an adaptive management component
both valuable and necessary within the context of 5-year regulations
for activities that have been associated with marine mammal mortality
in certain circumstances and locations.
The reporting requirements associated with this proposed rule are
designed to provide NMFS with monitoring data from the previous year to
allow NMFS to consider whether any changes are appropriate. NMFS and
the Navy would meet to discuss the monitoring reports, Navy R&D
developments, and current science and whether mitigation or monitoring
modifications are appropriate. The use of adaptive management allows
NMFS to consider new information from different sources to determine
(with input from the Navy regarding practicability) on an annual or
biennial basis if mitigation or monitoring measures should be modified
(including additions or deletions). Mitigation measures could be
modified if new data suggests that such modifications would have a
reasonable likelihood of reducing adverse effects to marine mammals and
if the measures are practicable.
The following are some of the possible sources of applicable data
to be considered through the adaptive management process: (1) Results
from monitoring and exercises reports, as required by MMPA
authorizations; (2) compiled results of Navy funded R&D

[[Page 9991]]

studies; (3) results from specific stranding investigations; (4)
results from general marine mammal and sound research; and (5) any
information which reveals that marine mammals may have been taken in a
manner, extent, or number not authorized by these regulations or
subsequent LOA.

Proposed Reporting

In order to issue an ITA for an activity, section 101(a)(5)(A) of
the MMPA states that NMFS must set forth ``requirements pertaining to
the monitoring and reporting of such taking''. Effective reporting is
critical both to compliance as well as ensuring that the most value is
obtained from the required monitoring. Some of the reporting
requirements are still in development and the final rulemaking may
contain additional details not contained here. Additionally, proposed
reporting requirements may be modified, removed, or added based on
information or comments received during the public comment period.
Reports from individual monitoring events, results of analyses,
publications, and periodic progress reports for specific monitoring
projects would be posted to the Navy's Marine Species Monitoring web
portal: http://www.navymarinespeciesmonitoring.us. Currently, there are
several different reporting requirements pursuant to these proposed
regulations:

General Notification of Injured or Dead Marine Mammals

Navy personnel would ensure that NMFS (the appropriate Regional
Stranding Coordinator) is notified immediately (or as soon as clearance
procedures allow) if an injured or dead marine mammal is found during
or shortly after, and in the vicinity of, any Navy training exercise
utilizing MFAS, HFAS, or underwater explosive detonations. The Navy
would provide NMFS with species identification or a description of the
animal(s), the condition of the animal(s) (including carcass condition
if the animal is dead), location, time of first discovery, observed
behaviors (if alive), and photographs or video (if available). The Navy
shall consult the Stranding Response Plan to obtain more specific
reporting requirements for specific circumstances.

Vessel Strike

NMFS has developed the following language to address monitoring and
reporting measures specific to vessel strike. Most of this language
comes directly from the Stranding Response Plan for other Navy training
and testing rulemakings. This section has also been included in the
regulatory text at the end of this proposed rule. Vessel strike during
Navy training activities in the Study Area is not anticipated; however,
in the event that a Navy vessel strikes a whale, the Navy shall do the
following:
Immediately report to NMFS (pursuant to the established
Communication Protocol) the:
Species identification (if known);
Location (latitude/longitude) of the animal (or location
of the strike if the animal has disappeared);
Whether the animal is alive or dead (or unknown); and
The time of the strike.
As soon as feasible, the Navy shall report to or provide to NMFS,
the:
Size, length, and description (critical if species is not
known) of animal;
An estimate of the injury status (e.g., dead, injured but
alive, injured and moving, blood or tissue observed in the water,
status unknown, disappeared, etc.);
Description of the behavior of the whale during event,
immediately after the strike, and following the strike (until the
report is made or the animal is no longer sighted);
Vessel class/type and operational status;
Vessel length;
Vessel speed and heading; and
To the best extent possible, obtain a photo or video of
the struck animal, if the animal is still in view.
Within 2 weeks of the strike, provide NMFS:
A detailed description of the specific actions of the
vessel in the 30-minute timeframe immediately preceding the strike,
during the event, and immediately after the strike (e.g., the speed and
changes in speed, the direction and changes in direction, other
maneuvers, sonar use, etc., if not classified);
A narrative description of marine mammal sightings during
the event and immediately after, and any information as to sightings
prior to the strike, if available; and use established Navy shipboard
procedures to make a camera available to attempt to capture photographs
following a ship strike.
NMFS and the Navy will coordinate to determine the services the
Navy may provide to assist NMFS with the investigation of the strike.
The response and support activities to be provided by the Navy are
dependent on resource availability, must be consistent with military
security, and must be logistically feasible without compromising Navy
personnel safety. Assistance requested and provided may vary based on
distance of strike from shore, the nature of the vessel that hit the
whale, available nearby Navy resources, operational and installation
commitments, or other factors.

Annual GOA TMAA Monitoring Report

The Navy shall submit an annual report of the GOA TMAA monitoring
describing the implementation and results from the previous calendar
year. Data collection methods will be standardized across range
complexes and study areas to allow for comparison in different
geographic locations. Although additional information will be gathered,
Navy Lookouts collecting marine mammal data pursuant to the GOA TMAA
monitoring plan shall, at a minimum, provide the same marine mammal
observation data required in Sec. 218.155. The report shall be
submitted either 90 days after the calendar year, or 90 days after the
conclusion of the monitoring year to be determined by the Adaptive
Management process. The GOA TMAA Monitoring Report may be provided to
NMFS within a larger report that includes the required Monitoring Plan
reports from multiple range complexes and study areas (the multi-Range
Complex Annual Monitoring Report). Such a report would describe
progress of knowledge made with respect to monitoring plan study
questions across all Navy ranges associated with the Integrated
Comprehensive Monitoring Program. Similar study questions shall be
treated together so that progress on each topic shall be summarized
across all Navy ranges. The report need not include analyses and
content that does not provide direct assessment of cumulative progress
on the monitoring plan study questions.

Annual GOA TMAA Exercise Report

Each year, the Navy shall submit a preliminary report detailing the
status of authorized sound sources within 21 days after the anniversary
of the date of issuance of the LOA. Each year, the Navy shall submit a
detailed report within 3 months after the anniversary of the date of
issuance of the LOA. The annual report shall contain information on
Major Training Exercises (MTEs), Sinking Exercise (SINKEX) events, and
a summary of all sound sources used (total hours or quantity [per the
LOA] of each bin of sonar or other non-impulsive source; total annual
number of each type of explosive exercises; and total annual expended/
detonated rounds [missiles, bombs, sonobuoys, etc.] for each explosive
bin). The analysis in the detailed report will be

[[Page 9992]]

based on the accumulation of data from the current year's report and
data collected from previous the report. Information included in the
classified annual reports may be used to inform future adaptive
management of activities within the GOA TMAA.

Sonar Exercise Notification

The Navy shall submit to NMFS (specific contact information to be
provided in LOA) an electronic report within fifteen calendar days
after the completion of any major training exercise indicating:
Location of the exercise; beginning and end dates of the exercise; and
type of exercise.

5-Year Close-Out Exercise Report

This report will be included as part of the 2021 annual exercise
report. This report will provide the annual totals for each sound
source bin with a comparison to the annual allowance and the 5-year
total for each sound source bin with a comparison to the 5-year
allowance. Additionally, if there were any changes to the sound source
allowance, this report will include a discussion of why the change was
made and include the analysis to support how the change did or did not
result in a change in the SEIS and final rule determinations. The
report will be submitted 3 months after the expiration of the rule.
NMFS will submit comments on the draft close-out report, if any, within
3 months of receipt. The report will be considered final after the Navy
has addressed NMFS' comments, or 3 months after the submittal of the
draft if NMFS does not provide comments.

Estimated Take of Marine Mammals

In the Potential Effects section, NMFS' analysis identified the
lethal responses, physical trauma, sensory impairment (PTS, TTS, and
acoustic masking), physiological responses (particular stress
responses), and behavioral responses that could potentially result from
exposure to MFAS/HFAS or underwater explosive detonations. In this
section, the potential effects to marine mammals from MFAS/HFAS and
underwater detonation of explosives will be related to the MMPA
regulatory definitions of Level A and Level B harassment and we will
attempt to quantify the effects that might occur from the proposed
training activities in the Study Area.
As mentioned previously, behavioral responses are context-
dependent, complex, and influenced to varying degrees by a number of
factors other than just received level. For example, an animal may
respond differently to a sound emanating from a ship that is moving
towards the animal than it would to an identical received level coming
from a vessel that is moving away, or to a ship traveling at a
different speed or at a different distance from the animal. At greater
distances, the nature of vessel movements could also potentially not
have any effect on the animal's response to the sound. In any case, a
full description of the suite of factors that elicited a behavioral
response would require a mention of the vicinity, speed and movement of
the vessel, or other factors. So, while sound sources and the received
levels are the primary focus of the analysis and those that are laid
out quantitatively in the regulatory text, it is with the understanding
that other factors related to the training sometimes contribute to the
behavioral responses of marine mammals, although they cannot be
quantified.

Definition of Harassment

As mentioned previously, with respect to military readiness
activities, section 3(18)(B) of the MMPA defines ``harassment'' as:
``(i) any act that injures or has the significant potential to injure a
marine mammal or marine mammal stock in the wild [Level A Harassment];
or (ii) any act that disturbs or is likely to disturb a marine mammal
or marine mammal stock in the wild by causing disruption of natural
behavioral patterns, including, but not limited to, migration,
surfacing, nursing, breeding, feeding, or sheltering, to a point where
such behavioral patterns are abandoned or significantly altered [Level
B Harassment].'' It is important to note that, as Level B harassment is
interpreted here and quantified by the behavioral thresholds described
below, the fact that a single behavioral pattern (of unspecified
duration) is abandoned or significantly altered and classified as a
Level B take does not mean, necessarily, that the fitness of the
harassed individual is affected either at all or significantly, or
that, for example, a preferred habitat area is abandoned. Further
analysis of context and duration of likely exposures and effects is
necessary to determine the impacts of the estimated effects on
individuals and how those may translate to population level impacts,
and is included in the Analysis and Negligible Impact Determination.

Level B Harassment

Of the potential effects that were described earlier in this
proposed rule, the following are the types of effects that fall into
the Level B harassment category:
Behavioral Harassment--Behavioral disturbance that rises to the
level described in the definition above, when resulting from exposures
to non-impulsive or impulsive sound, is considered Level B harassment.
Some of the lower level physiological stress responses discussed
earlier would also likely co-occur with the predicted harassments,
although these responses are more difficult to detect and fewer data
exist relating these responses to specific received levels of sound.
When Level B harassment is predicted based on estimated behavioral
responses, those takes may have a stress-related physiological
component as well. Except for some vocalization changes that may be
compensating for auditory masking, all behavioral reactions are assumed
to occur due to a preceding stress or cueing response; however, stress
responses cannot be predicted directly due to a lack of scientific
data. Responses can overlap; for example, an increased respiration rate
is likely to be coupled to a flight response or other avoidance
behavior. Factors to consider when trying to predict a stress response
include the mammal's life history stage and whether they are na[iuml]ve
or experienced with the sound. Prior experience with a stressor may be
of particular importance as repeated experience with a stressor may
dull the stress response via acclimation (St. Aubin and Dierauf, 2001;
Bejder et al., 2009).
As the statutory definition is currently applied, a wide range of
behavioral reactions may qualify as Level B harassment under the MMPA,
including but not limited to avoidance of the sound source, temporary
changes in vocalizations or dive patters, temporary avoidance of an
area, or temporary disruption of feeding, migrating, or reproductive
behaviors. The estimates calculated by the Navy using the acoustic
thresholds do not differentiate between the different types of
potential behavioral reactions. Nor do the estimates provide
information regarding the potential fitness or other biological
consequences of the reactions on the affected individuals. We therefore
consider the available scientific evidence to determine the likely
nature of the modeled behavioral responses and the potential fitness
consequences for affected individuals.
Acoustic Masking and Communication Impairment--Acoustic masking and
communication impairment are considered Level B harassment as they can
disrupt natural behavioral patterns by interrupting or limiting the
marine mammal's receipt or transmittal of important information or

[[Page 9993]]

environmental cues. As discussed in the Analysis and Negligible Impact
Determination later in this proposed rule, masking effects from MFAS/
HFAS are expected to be minimal. If masking or communication impairment
were to occur briefly, it would be in the frequency range of MFAS,
which overlaps with some marine mammal vocalizations; however, it would
likely not mask the entirety of any particular vocalization,
communication series, or other critical auditory cue, because the
signal length, frequency, and duty cycle of the MFAS/HFAS signal does
not perfectly mimic the characteristics of any marine mammal's
vocalizations. The other sources used in Navy training, many of either
higher frequencies (meaning that the sounds generated attenuate even
closer to the source) or lower amounts of operation, are similarly not
expected to result in masking or communication impairment.
Temporary Threshold Shift (TTS)--As discussed previously, TTS can
affect how an animal behaves in response to the environment, including
conspecifics, predators, and prey. The following physiological
mechanisms are thought to play a role in inducing auditory fatigue:
Effects to sensory hair cells in the inner ear that reduce their
sensitivity, modification of the chemical environment within the
sensory cells; residual muscular activity in the middle ear,
displacement of certain inner ear membranes; increased blood flow; and
post-stimulatory reduction in both efferent and sensory neural output.
Ward (1997) suggested that when these effects result in TTS rather than
PTS, they are within the normal bounds of physiological variability and
tolerance and do not represent a physical injury. Additionally,
Southall et al. (2007) indicate that although PTS is a tissue injury,
TTS is not because the reduced hearing sensitivity following exposure
to intense sound results primarily from fatigue, not loss, of cochlear
hair cells and supporting structures and is reversible. Accordingly,
NMFS classifies TTS (when resulting from exposure to sonar and other
active acoustic sources and explosives and other impulsive sources) as
Level B harassment, not Level A harassment (injury).
The sound characteristics that correlate with specific stress
responses in marine mammals are poorly understood. Therefore, in
practice, a stress response is assumed if a physiological reaction such
as a hearing loss (threshold shift--i.e., TTS or PTS) or trauma is
predicted (or if a behavioral response is predicted, as discussed in
the Level B Harassment section).
Only non-TTS behavioral reactions and TTS are anticipated with the
GOA TMAA training activities, and these Level B behavioral harassment
takes are enumerated in Tables 12 and 13 and in the Negligible Impact
Determination later in this proposed rule.

Level A Harassment

Of the potential effects that were described earlier, following are
the types of effects that can fall into the Level A harassment category
(unless they further rise to the level of serious injury or mortality):
Permanent Threshold Shift (PTS)--PTS (resulting either from
exposure to MFAS/HFAS or explosive detonations) is irreversible and
considered an injury. PTS results from exposure to intense sounds that
cause a permanent loss of inner or outer cochlear hair cells or exceed
the elastic limits of certain tissues and membranes in the middle and
inner ears and result in changes in the chemical composition of the
inner ear fluids. As mentioned above for TTS, a stress response is
assumed if a physiological reaction such as a hearing loss (PTS) or
trauma is predicted.
As discussed in the Negligible Impact Determination later in this
proposed rule, only a small number (5) of Level A takes resulting from
mild levels of PTS are predicted, and no serious injury or mortality
takes are predicted, with the Navy's training activities in the GOA
TMAA.
Tissue Damage due to Acoustically Mediated Bubble Growth--A few
theories suggest ways in which gas bubbles become enlarged through
exposure to intense sounds (MFAS/HFAS) to the point where tissue damage
results. In rectified diffusion, exposure to a sound field would cause
bubbles to increase in size which could cause tissue damage that would
be considered injurious. A short duration of sonar pings (such as that
which an animal exposed to MFAS would be most likely to encounter)
would not likely be long enough to drive bubble growth to any
substantial size. Alternately, bubbles could be destabilized by high-
level sound exposures such that bubble growth then occurs through
static diffusion of gas out of the tissues. The degree of
supersaturation and exposure levels observed to cause microbubble
destabilization are unlikely to occur, either alone or in concert
because of how close an animal would need to be to the sound source to
be exposed to high enough levels, especially considering the likely
avoidance of the sound source and the required mitigation. For the
reasons above, Level A harassment in the form of tissue damage from
acoustically mediated bubble growth is not predicted for training
activities in the GOA TMAA.
Tissue Damage due to Behaviorally Mediated Bubble Growth--Several
authors suggest mechanisms in which marine mammals could behaviorally
respond to exposure to MFAS/HFAS by altering their dive patterns
(unusually rapid ascent, unusually long series of surface dives, etc.)
in a manner that might result in unusual bubble formation or growth
ultimately resulting in tissue damage. In this scenario, the rate of
ascent would need to be sufficiently rapid to compromise behavioral or
physiological protections against nitrogen bubble formation.
There is considerable disagreement among scientists as to the
likelihood of this phenomenon (Piantadosi and Thalmann, 2004; Evans and
Miller, 2003). Although it has been argued that traumas from recent
beaked whale strandings are consistent with gas emboli and bubble-
induced tissue separations (Jepson et al., 2003; Fernandez et al.,
2005; Fern[aacute]ndez et al., 2012), nitrogen bubble formation as the
cause of the traumas has not been verified. If tissue damage does occur
by this phenomenon, it would be considered an injury. Recent modeling
by Kvadsheim et al. (2012) determined that while behavioral and
physiological responses to sonar have the potential to result in bubble
formation, the actual observed behavioral responses of cetaceans to
sonar did not imply any significantly increased risk over what may
otherwise occur normally in individual marine mammals. Level A
harassment in the form of tissue damage from behaviorally mediated
bubble growth is not anticipated for training activities in the GOA
TMAA.
Physical Disruption of Tissues Resulting from Explosive Shock
Wave--Physical damage of tissues resulting from a shock wave (from an
explosive detonation) is classified as an injury. Blast effects are
greatest at the gas-liquid interface (Landsberg, 2000) and gas-
containing organs, particularly the lungs and gastrointestinal tract,
are especially susceptible (Goertner, 1982; Hill 1978; Yelverton et
al., 1973). Nasal sacs, larynx, pharynx, trachea, and lungs may be
damaged by compression/expansion caused by the oscillations of the
blast gas bubble (Reidenberg and Laitman, 2003). Severe damage (from
the shock wave) to the ears can include tympanic membrane rupture,
fracture of the ossicles, damage to the cochlea, hemorrhage, and
cerebrospinal fluid leakage into the middle ear. Explosions in the
ocean or near the water surface can introduce loud, impulsive,

[[Page 9994]]

broadband sounds into the marine environment. These sounds are likely
within the audible range of most marine mammals, but the duration of
individual sounds is very short. The direct sound from explosions used
during training activities last less than a second, and most events
involve the use of only one or a few explosions. Furthermore, events
are dispersed in time and throughout the GOA TMAA Study Area. These
factors reduce the likelihood of these sources causing substantial
physical disruption of tissues in marine mammals, especially when the
avoidance and mitigation factors are taken into consideration.
Consequently, no Level A harassment from explosive shock waves is
anticipated from training activities in the GOA TMAA.
Vessel or Ordnance Strike--Vessel strike or ordnance strike
associated with the specified activities would be considered Level A
harassment, serious injury, or mortality. There are no records of any
Navy vessel strikes to marine mammals during training activities in the
GOA TMMA Study Area. There have been Navy strikes of large whales in
areas outside the Study Area, such as Hawaii and Southern California.
However, these areas differ significantly from the Study Area given
that both Hawaii and Southern California have a much higher number of
Navy vessel activities and much higher densities of large whales. The
Navy's proposed actions would not result in any appreciable changes in
locations or frequency of vessel activity, and there have been no whale
strikes during any previous training activities in the Study Area. The
manner in which the Navy has trained would remain consistent with the
range of variability observed over the last decade so the Navy does not
anticipate vessel strikes would occur within the Study Area during
training events. As such, vessel or ordnance strike is not anticipated
with the Navy activities in the Study Area and Level A harassment,
serious injury, or mortality are not expected.

Take Thresholds

For the purposes of an MMPA authorization, three types of take are
identified: Level B harassment; Level A harassment; and mortality (or
serious injury leading to mortality). The categories of marine mammal
responses (physiological and behavioral) that fall into the two
harassment categories were described in the previous section.
Because the physiological and behavioral responses of the majority
of the marine mammals exposed to non-impulse and impulse sounds cannot
be easily detected or measured, and because NMFS must authorize take
prior to the impacts to marine mammals, a method is needed to estimate
the number of individuals that will be taken, pursuant to the MMPA,
based on the proposed action. To this end, NMFS developed acoustic
thresholds that estimate at what received level (when exposed to non-
impulse or impulse sounds) Level B harassment and Level A harassment of
marine mammals would occur. The acoustic thresholds for non-impulse and
impulse sounds are discussed below.
Level B Harassment Threshold (TTS)--Behavioral disturbance,
acoustic masking, and TTS are all considered Level B harassment. Marine
mammals would usually be behaviorally disturbed at lower received
levels than those at which they would likely sustain TTS, so the levels
at which behavioral disturbance are likely to occur is considered the
onset of Level B harassment. The behavioral responses of marine mammals
to sound are variable, context specific, and, therefore, difficult to
quantify (see Risk Function section, below).
TTS is a physiological effect that has been studied and quantified
in laboratory conditions. Because data exist to support an estimate of
the received levels at which marine mammals will incur TTS, NMFS uses
an acoustic criteria to estimate the number of marine mammals that
might sustain TTS. TTS is a subset of Level B harassment (along with
sub-TTS behavioral harassment) and the Navy is not specifically
required to estimate those numbers; however, the more specifically the
affected marine mammal responses can be estimated, the better the
analysis.
Level A Harassment Threshold (PTS)--For acoustic effects, because
the tissues of the ear appear to be the most susceptible to the
physiological effects of sound, and because threshold shifts tend to
occur at lower exposures than other more serious auditory effects, NMFS
has determined that PTS is the best indicator for the smallest degree
of injury that can be measured. Therefore, the acoustic exposure
associated with onset-PTS is used to define the lower limit of Level A
harassment.
PTS data do not currently exist for marine mammals and are unlikely
to be obtained due to ethical concerns. However, PTS levels for these
animals may be estimated using TTS data from marine mammals and
relationships between TTS and PTS that have been determined through
study of terrestrial mammals.
We note here that behaviorally mediated injuries (such as those
that have been hypothesized as the cause of some beaked whale
strandings) could potentially occur in response to received levels
lower than those believed to directly result in tissue damage. As
mentioned previously, data to support a quantitative estimate of these
potential effects (for which the exact mechanism is not known and in
which factors other than received level may play a significant role) do
not exist. However, based on the number of years (more than 60) and
number of hours of MFAS per year that the U.S. (and other countries)
has operated compared to the reported (and verified) cases of
associated marine mammal strandings, NMFS believes that the probability
of these types of injuries is very low. Tables 9 and 10 provide a
summary of non-impulsive and impulsive thresholds to TTS and PTS for
marine mammals. A detailed explanation of how these thresholds were
derived is provided in the Criteria and Thresholds Technical Report
(Finneran and Jenkins, 2012) and summarized in Chapter 6 of the LOA
application (http://www.nmfs.noaa.gov/pr/permits/incidental/military.htm).

Table 9--Onset TTS and PTS Thresholds for Non-Impulse Sound
----------------------------------------------------------------------------------------------------------------
Group Species Onset TTS Onset PTS
----------------------------------------------------------------------------------------------------------------
Low-Frequency Cetaceans.............. All mysticetes......... 178 dB re 1[micro]Pa2- 198 dB re 1[micro]Pa2-
sec(LFII). sec(LFII).
Mid-Frequency Cetaceans.............. Most delphinids, beaked 178 dB re 1[micro]Pa2- 198 dB re 1[micro]Pa2-
whales, medium and sec(MFII). sec(MFII).
large toothed whales.
High-Frequency Cetaceans............. Porpoises, Kogia spp... 152 dB re 1[micro]Pa2- 172 dB re 1[micro]Pa2-
sec(HFII). secSEL (HFII).
Phocidae In-water.................... Harbor, Hawaiian monk, 183 dB re 1[micro]Pa2- 197 dB re 1[micro]Pa2-
elephant seals. sec(PWI). sec(PWI).

[[Page 9995]]

Otariidae & Obodenidae In-water...... Sea lions and fur seals 206 dB re 1[micro]Pa2- 220 dB re 1[micro]Pa2-
sec(OWI). sec(OWI).
Mustelidae In-water.................. Sea otters.............
----------------------------------------------------------------------------------------------------------------
LFII, MFII, HFII: New compound Type II weighting functions; PWI, OWI: Original Type I (Southall et al., 2007)
for pinniped and mustelid in water.

[GRAPHIC] [TIFF OMITTED] TP26FE16.000

Level B Harassment Risk Function (Behavioral Harassment)

As the statutory definition is currently applied, a wide range of
behavioral reactions may qualify as Level B harassment under the MMPA,
including but not limited to avoidance of the sound source, temporary
changes in vocalizations or dive patters, temporary avoidance of an
area, or temporary disruption of feeding, migrating, or reproductive
behaviors. The estimates

[[Page 9996]]

calculated by the Navy using the acoustic thresholds do not
differentiate between the different types of potential behavioral
reactions. Nor do the estimates provide information regarding the
potential fitness or other biological consequences of the reactions on
the affected individuals. We therefore consider the available
scientific evidence to determine the likely nature of the modeled
behavioral responses and the potential fitness consequences for
affected individuals.
Behavioral Response Criteria for Non-Impulsive Sound from Sonar and
other Active Sources--In 2006, NMFS issued the first MMPA authorization
to allow the take of marine mammals incidental to MFAS (to the Navy for
RIMPAC). For that authorization, NMFS used 173 dB SEL as the criterion
for the onset of behavioral harassment (Level B harassment). This type
of single number criterion is referred to as a step function, in which
(in this example) all animals estimated to be exposed to received
levels above 173 db SEL would be predicted to be taken by Level B
Harassment and all animals exposed to less than 173 dB SEL would not be
taken by Level B harassment. As mentioned previously, marine mammal
behavioral responses to sound are highly variable and context specific
(affected by differences in acoustic conditions; differences between
species and populations; differences in gender, age, reproductive
status, or social behavior; or the prior experience of the
individuals), which means that there is support for alternate
approaches for estimating behavioral harassment.
Unlike step functions, acoustic risk continuum functions (which are
also called ``exposure-response functions'' or ``dose-response
functions'' in other risk assessment contexts) allow for probability of
a response that NMFS would classify as harassment to occur over a range
of possible received levels (instead of one number) and assume that the
probability of a response depends first on the ``dose'' (in this case,
the received level of sound) and that the probability of a response
increases as the ``dose'' increases. In January 2009, NMFS issued three
final rules governing the incidental take of marine mammals (within
Navy's Hawaii Range, Southern California Training and Testing Range,
and Atlantic Fleet Active Sonar Training complexes) that used a risk
continuum to estimate the percent of marine mammals exposed to various
levels of MFAS that would respond in a manner NMFS considers
harassment.
The Navy and NMFS have previously used acoustic risk functions to
estimate the probable responses of marine mammals to acoustic exposures
for other training and research programs. Examples of previous
application include the Navy FEISs on the Surveillance Towed Array
Sensor System Low Frequency Active (SURTASS LFA) sonar (U.S. Department
of the Navy, 2001c); the North Pacific Acoustic Laboratory experiments
conducted off the Island of Kauai (Office of Naval Research, 2001), and
the Supplemental EIS for SURTASS LFA sonar (U.S. Department of the
Navy, 2007d). As discussed earlier, factors other than received level
(such as distance from or bearing to the sound source, context of
animal at time of exposure) can affect the way that marine mammals
respond; however, data to support a quantitative analysis of those (and
other factors) do not currently exist. It is also worth specifically
noting that while context is very important in marine mammal response,
given otherwise equivalent context, the severity of a marine mammal
behavioral response is also expected to increase with received level
(Houser and Moore, 2014). NMFS will continue to modify these criteria
as new data become available and can be appropriately and effectively
incorporated.
The particular acoustic risk functions developed by NMFS and the
Navy (see Figures 1 and 2 of the LOA application) estimate the
probability of behavioral responses to MFAS/HFAS (interpreted as the
percentage of the exposed population) that NMFS would classify as
harassment for the purposes of the MMPA given exposure to specific
received levels of MFAS/HFAS. The mathematical function (below)
underlying this curve is a cumulative probability distribution adapted
from a solution in Feller (1968) and was also used in predicting risk
for the Navy's SURTASS LFA MMPA authorization as well.
[GRAPHIC] [TIFF OMITTED] TP26FE16.001

Where:
R = Risk (0--1.0)
L = Received level (dB re: 1 [micro]Pa)
B = Basement received level = 120 dB re: 1 [micro]Pa
K = Received level increment above B where 50-percent risk = 45 dB
re: 1 [micro]Pa
A = Risk transition sharpness parameter = 10 (odontocetes and
pinnipeds) or 8 (mysticetes)

Detailed information on the above equation and its parameters is
available in the LOA application and previous Navy documents listed
above.
The harbor porpoise and beaked whales have unique criteria based on
specific data that show these animals to be especially sensitive to
sound. Harbor porpoise and beaked whale non-impulsive behavioral
criteria are used unweighted--without weighting the received level
before comparing it to the threshold (see Finneran and Jenkins, 2012).
It has been speculated for some time that beaked whales might have
unusual sensitivities to sonar sound due to their likelihood of
stranding in conjunction with mid-frequency sonar use, even in areas
where other species were more abundant (D'Amico et al., 2009), but
there were not sufficient data to support a separate treatment for
beaked whales until recently. With the recent publication of results
from Blainville's beaked whale monitoring and experimental exposure
studies on the instrumented AUTEC range in the Bahamas (McCarthy et al.
2011; Tyack et al. 2011), there are now statistically strong data
suggesting that beaked whales tend to avoid actual naval mid-frequency
sonar in real anti-submarine training scenarios as well as playbacks of
killer whale vocalizations, and other anthropogenic sounds. Tyack et
al. (2011) report that, in reaction to sonar playbacks, most beaked
whales stopped echolocating, made long slow ascent, and moved away from
the sound. During an exercise using mid-frequency sonar, beaked whales
avoided the sonar acoustic footprint at a distance where the received
level was ``around 140 dB'' (SPL) and once the exercise ended, beaked
whales re-inhabited the center of exercise area within 2-3 days (Tyack
et al., 2011). The Navy has therefore adopted an unweighted 140 dB re 1
[micro]Pa SPL threshold for significant behavioral effects for all
beaked whales (family: Ziphiidae).
Since the development of the criterion, analysis of the data the
2010 and 2011 field seasons of the southern California Behavioral
Responses Study have been published. The study, DeRuiter et al.
(2013b), provides similar evidence of Cuvier's beaked whale
sensitivities to sound based on two controlled exposures. Two whales,
one in each season, were tagged and exposed to simulated mid-frequency
active sonar at distances of 3.4-9.5 km. The 2011 whale was also
incidentally exposed to mid-frequency active sonar from a distant naval
exercise (approximately 118 km away). Received levels from the mid-
frequency active sonar signals during the controlled and incidental
exposures were calculated as

[[Page 9997]]

84-144 and 78-106 dB re 1 [micro]Pa rms, respectively. Both whales
showed responses to the controlled exposures, ranging from initial
orientation changes to avoidance responses characterized by energetic
fluking and swimming away from the source. However, the authors did not
detect similar responses to incidental exposure to distant naval sonar
exercises at comparable received levels, indicating that context of the
exposures (e.g., source proximity, controlled source ramp-up) may have
been a significant factor. Because the sample size was limited
(controlled exposures during a single dive in both 2010 and 2011) and
baseline behavioral data was obtained from different stocks and
geographic areas (i.e., Hawaii and Mediterranean Sea), and the
responses exhibited to controlled exposures were not exhibited by an
animal exposed to some of the same received levels of real sonar
exercises, the Navy relied on the studies at the AUTEC that analyzed
beaked whale responses to actual naval exercises using mid-frequency
active sonar to evaluate potential behavioral responses by beaked
whales to proposed training and testing activities using sonar and
other active acoustic sources.
The information currently available regarding harbor porpoises
suggests a very low threshold level of response for both captive and
wild animals. Threshold levels at which both captive (Kastelein et al.,
2000; Kastelein et al., 2005; Kastelein et al., 2006; Kastelein et al.,
2008) and wild harbor porpoises (Johnston, 2002) responded to sound
(e.g., acoustic harassment devices, acoustic deterrent devices, or
other non-impulsive sound sources) are very low (e.g., approximately
120 dB re 1 [mu]Pa). Therefore, a SPL of 120 dB re 1 [mu]Pa is used in
this analysis as a threshold for predicting behavioral responses in
harbor porpoises instead of the risk functions used for other species
(i.e., we assume for the purpose of estimating take that all harbor
porpoises exposed to 120 dB or higher MFAS/HFAS will be taken by Level
B behavioral harassment).
Behavioral Response Criteria for Impulsive Sound from Explosions --
If more than one explosive event occurs within any given 24-hour period
within a training or testing event, behavioral criteria are applied to
predict the number of animals that may be taken by Level B harassment.
For multiple explosive events the behavioral threshold used in this
analysis is 5 dB less than the TTS onset threshold (in sound exposure
level). This value is derived from observed onsets of behavioral
response by test subjects (bottlenose dolphins) during non-impulse TTS
testing (Schlundt et al., 2000). Some multiple explosive events, such
as certain naval gunnery exercises, may be treated as a single
impulsive event because a few explosions occur closely spaced within a
very short period of time (a few seconds). For single impulses at
received sound levels below hearing loss thresholds, the most likely
behavioral response is a brief alerting or orienting response. Since no
further sounds follow the initial brief impulses, Level B take in the
form of behavioral harassment beyond that associated with potential TTS
would not be expected to occur. This reasoning was applied to previous
shock trials (63 FR 230; 66 FR 87; 73 FR 143) and is extended to these
Phase 2 criteria. Behavioral thresholds for impulsive sources are
summarized in Table 11 and further detailed in the LOA application.
Since impulse events can be quite short, it may be possible to
accumulate multiple received impulses at sound pressure levels
considerably above the energy-based criterion and still not be
considered a behavioral take. The Navy treats all individual received
impulses as if they were one second long for the purposes of
calculating cumulative sound exposure level for multiple impulse
events. For example, five air gun impulses, each 0.1 second long,
received at a Type II weighted sound pressure level of 167 dB SPL would
equal a 164 dB sound exposure level, and would not be predicted as
leading to a significant behavioral response (take) in MF or HF
cetaceans. However, if the five 0.1 second pulses are treated as a 5
second exposure, it would yield an adjusted SEL of approximately 169
dB, exceeding the behavioral threshold of 167 dB SEL. For impulses
associated with explosions that have durations of a few microseconds,
this assumption greatly overestimates effects based on sound exposure
level metrics such as TTS and PTS and behavioral responses. Appropriate
weighting values will be applied to the received impulse in one-third
octave bands and the energy summed to produce a total weighted sound
exposure level value. For impulsive behavioral criteria, the Navy's
weighting functions (detailed in Chapter 6 of the LOA application) are
applied to the received sound level before being compared to the
threshold.

Table 11--Behavioral Thresholds for Impulsive Sound
------------------------------------------------------------------------
Impulsive
behavioral
Hearing group threshold for > 2 Onset TTS
pulses/24 hours
------------------------------------------------------------------------
Low-Frequency Cetaceans......... 167 dB SEL (LFII). 172 dB SEL (MFII)
or 224 dB Peak
SPL.
Mid-Frequency Cetaceans......... 167 dB SEL (MFII).
High-Frequency Cetaceans........ 141 dB SEL (HFII). 146 dB SEL (HFII)
or 195 dB Peak
SPL.
Phocid Seals (in water)......... 172 dB SEL (PWI).. 177 dB SEL (PWI)
or 212 dB Peak
SPL.
Otariidae & Mustelidae (in 195 dB SEL (OWI).. 200 dB SEL (OWI)
water). or 212 dB Peak
SPL.
------------------------------------------------------------------------
Notes: (1) LFII, MFII, HFII are New compound Type II weighting
functions; PWI, OWI = Original Type I (Southall et al., 2007) for
pinniped and mustelid in water (see Finneran and Jenkins 2012). (2)
SEL = re 1 [mu]Pa\2\-s; SPL = re 1 [mu]Pa, SEL = Sound Exposure Level,
dB = decibel, SPL = Sound Pressure Level.

Marine Mammal Density Estimates

A quantitative impact analysis requires an estimate of the number
of animals that might be affected by anthropogenic activities. A key
element of this estimation is knowledge of the abundance and
concentration of the species in specific areas where those activities
will occur. The most appropriate unit of metric for this type of
analysis is animal density, or the number of animals present per unit
area. Marine species density estimation requires a significant amount
of effort to both collect and analyze data to produce a reasonable
estimate. Unlike surveys for terrestrial wildlife, many marine species
spend much of their time submerged, and are not easily observed. In
order to collect enough sighting data to make reasonable density
estimates, multiple observations are required, often in areas that are
not easily accessible (e.g., far offshore). Ideally, marine species
sighting data would be collected for the specific area and time period
(e.g., season) of interest and density estimates derived accordingly.
However, in many places, poor weather conditions and high sea states
prohibit

[[Page 9998]]

the completion of comprehensive visual surveys.
For most cetacean species, abundance is estimated using line-
transect surveys or mark-recapture studies (e.g., Barlow, 2010, Barlow
and Forney, 2007, Calambokidis et al., 2008). The result provides one
single density estimate value for each species across broad geographic
areas, such as waters within the U.S. EEZ off California, Oregon, and
Washington. This is the general approach applied in estimating cetacean
abundance in the NMFS Stock Assessment Reports. Although the single
value provides a good average estimate of abundance (total number of
individuals) for a specified area, it does not provide information on
the species distribution or concentrations within that area, and it
does not estimate density for other timeframes or seasons that were not
surveyed. More recently, habitat modeling has been used to estimate
cetacean densities (Barlow et al., 2009; Becker et al., 2010, 2012a, b,
c; Ferguson et al., 2006a; Forney et al., 2012; Redfern et al., 2006).
These models estimate cetacean density as a continuous function of
habitat variables (e.g., sea surface temperature, seafloor depth, etc.)
and thus allow predictions of cetacean densities on finer spatial
scales than traditional line-transect or mark-recapture analyses.
Within the geographic area that was modeled, densities can be predicted
wherever these habitat variables can be measured or estimated.
Uncertainty in published density estimates is typically large
because of the low number of sightings available for their derivation.
Uncertainty is typically expressed by the coefficient of variation (CV)
of the estimate, which is derived using standard statistical methods
and describes the amount of variation with respect to the population
mean. It is expressed as a fraction or sometimes a percentage and can
range upward from zero, indicating no uncertainty, to high values. For
example, a CV of 0.85 would indicate high uncertainty in the population
estimate. When the CV exceeds 1.0, the estimate is very uncertain. The
uncertainty associated with movements of animals into or out of an area
(due to factors such as availability of prey or changing oceanographic
conditions) is much larger than is indicated by the CV.
The methods used to estimate pinniped at-sea densities are
typically different than those used for cetaceans. This is discussed in
more detail in the Navy Marine Species Density Database Technical
Report (U.S. Department of the Navy, 2014). Pinniped abundance is
generally estimated via shore counts of animals at known rookeries and
haulout sites. Translating these numbers to in-water densities is
difficult given the variability in foraging ranges, migration, and
haulout behavior between species and within each species, and is driven
by factors such as age class, sex class, seasonal variation, etc.
Details of the density derivation for each species of pinniped in the
Study Area are provided in the U.S. Department of the Navy (2014). In
summary, the methods used to derive pinniped densities involved a
series of species-specific data reviews to compile the most accurate
and up-to-date information available. The total abundance divided by
the area of the region was the resultant density estimate for each
species in a given location.
There is no single source of density data for every area, marine
mammal species, and season because of the fiscal costs, resources, and
effort involved to provide enough survey coverage to sufficiently
estimate density. NMFS Southwest Fisheries Science Center conducts
standard U.S. West Coast surveys every 5-6 years and cannot
logistically support more frequent studies. The U.S. Navy has funded
two previous marine mammal surveys in the GOA TMAA (Rone et al., 2009,
2014) in the summer time-period when Navy training activities are most
likely to occur. The density data used to quantitatively estimate
impacts to marine mammals from Navy training in the GOA TMAA are based
on the best available science and were agreed upon with NMFS as a
cooperating agency for the SEIS/OEIS. As the federal regulator for the
MMPA, the NMFS role included having staff biologists review and comment
on the analysis and the SEIS/OEIS. The review also included
coordination with NMFS regional scientists from the Southwest Fisheries
Science Center and Alaska Fisheries Science Center on the latest
emergent data presented in their Pacific Stock Assessment Reports.
In May 2015, the Marine Mammal Commission also reviewed the Marine
Species Density Database Technical Report (U.S. Department of the Navy,
2014) and pointed out some textual errors that the Navy subsequently
corrected, but otherwise did not identify any changes in the data used
for acoustic effects modeling.
A certain number of sightings are required to generate the quality
of data necessary to produce either traditional line-transect density
estimates or spatial habitat modeled density values. The at-sea
identification of some species of specific MMPA designated stocks is
not always possible from available field data, nor would additional
data collection likely address the identification issue based on low
animal occurrence (e.g., Western North Pacific gray whale), cryptic
behaviors (e.g., beaked whales), and appearance similarities between
stocks (e.g., Steller sea lions). In the absence of species-specific
population survey data for these species, density estimates are derived
from different methods and data sources, based on NMFS recommendations.
The different methods for each of these species are described in
Section 3.8.3.1.6.1 (Marine Species Density Data) of the DSEIS/OEIS and
the Marine Species Density Database Technical Report (U.S. Department
of the Navy, 2014). NMFS and Navy have determined that these
alternative density estimates are sufficient for determining the
impacts of Navy training on these marine mammals under all applicable
statutes, and therefore are the best available science.
Therefore, to characterize marine mammal density for areas of
concern, including the GOA TMAA Study Area, the Navy compiled data from
multiple sources. Each data source may use different methods to
estimate density and uncertainty (e.g., variance) associated with the
estimates.
The Navy thus developed a protocol to select the best available
data sources based on species, area, and time (season). The Navy then
used this protocol to identify the best density data from available
sources, including habitat-based density models, line-transect
analyses, and peer-reviewed published studies. These data were
incorporated into a Geographic Information System database that
includes seasonal (summer/fall and winter/spring) density values for
every marine mammal species present within the Study Area. Detailed
information on the Navy's selection protocol, datasets, and specific
density values are provided in the Navy Marine Species Density Database
Technical Report (U.S. Department of the Navy, 2014).

Quantitative Modeling To Estimate Take for Impulsive and Non-Impulsive
Sound

The Navy performed a quantitative analysis to estimate the number
of marine mammals that could be affected by acoustic sources or
explosives used during Navy training activities. Inputs to the
quantitative analysis include marine mammal density estimates; marine
mammal depth occurrence distributions; oceanographic and environmental
data; marine mammal hearing data; and criteria and thresholds for
levels of potential effects. The quantitative analysis consists of

[[Page 9999]]

computer modeled estimates and a post-model analysis to determine the
number of potential mortalities and harassments. The model calculates
sound energy propagation from sonar, other active acoustic sources, and
explosives during naval activities; the sound or impulse received by
animat (virtual representation of an animal) dosimeters representing
marine mammals distributed in the area around the modeled activity; and
whether the sound or impulse received by a marine mammal exceeds the
thresholds for effects. The model estimates are then further analyzed
to consider animal avoidance and implementation of mitigation measures,
resulting in final estimates of potential effects due to Navy training.
Various computer models and mathematical equations can be used to
predict how energy spreads from a sound source (e.g., sonar or
underwater detonation) to a receiver (e.g., dolphin or sea turtle).
Basic underwater sound models calculate the overlap of energy and
marine life using assumptions that account for the many, variable, and
often unknown factors that can influence the result. Assumptions in
previous and current Navy models have intentionally erred on the side
of overestimation when there are unknowns or when the addition of other
variables was not likely to substantively change the final analysis.
For example, because the ocean environment is extremely dynamic and
information is often limited to a synthesis of data gathered over wide
areas and requiring many years of research, known information tends to
be an average of a seasonal or annual variation. El Ni[ntilde]o
Southern Oscillation events of the ocean-atmosphere system are an
example of dynamic change where unusually warm or cold ocean
temperatures are likely to redistribute marine life and alter the
propagation of underwater sound energy. Previous Navy modeling
therefore made some assumptions indicative of a maximum theoretical
propagation for sound energy (such as a perfectly reflective ocean
surface and a flat seafloor).
More complex computer models build upon basic modeling by factoring
in additional variables in an effort to be more accurate by accounting
for such things as variable bathymetry and an animal's likely presence
at various depths.
The Navy has developed new software tools, up to date marine mammal
density data, and other oceanographic data for the quantification of
estimated acoustic impacts to marine mammal impacts from Navy
activities. This new approach is the resulting evolution of the basic
model previously used by the Navy and reflects a more complex modeling
approach as described below. The new model, NAEMO, is the standard
model now used by the navy to estimate the potential acoustic effects
of Navy training and testing activities on marine mammals. Although
this more complex computer modeling approach accounts for various
environmental factors affecting acoustic propagation, the current
software tools do not consider the likelihood that a marine mammal
would attempt to avoid repeated exposures to a sound or avoid an area
of intense activity where a training or testing event may be focused.
Additionally, the software tools do not consider the implementation of
mitigation (e.g., stopping sonar transmissions when a marine mammal is
within a certain distance of a ship or mitigation zone clearance prior
to detonations). In both of these situations, naval activities are
modeled as though an activity would occur regardless of proximity to
marine mammals and without any horizontal movement by the animal away
from the sound source or human activities. Therefore, the final step of
the quantitative analysis of acoustic effects is to consider the
implementation of mitigation and the possibility that marine mammals
would avoid continued or repeated sound exposures. This final, post-
analysis step in the modeling process is meant to better quantify the
predicted effects by accounting for likely animal avoidance behavior
and implementation of standard Navy mitigations.
The incorporation of mitigation factors for the reduction of
predicted effects used a conservative approach (erring on the side of
overestimating the number of effects) since reductions as a result of
implemented mitigation were only applied to those events having a very
high likelihood of detecting marine mammals.
The steps of the quantitative analysis of acoustic effects, the
values and assumptions that went into the Navy's model, and the
resulting ranges to effects are detailed in Chapter 6 (Section 6.5) of
the LOA application (http://www.nmfs.noaa.gov/pr/permits/incidental/).
Details of the model's processes and the description and derivation of
the inputs are presented in the Navy's Determination of Acoustic
Effects technical Report (Marine Species Modeling Team, 2014). The
post-model analysis, which considers the potential for avoidance and
highly effective mitigation during the use of sonar and other active
acoustic sources and explosives, is described in Section 6.5 of the LOA
application. A detailed explanation of the post-model acoustic effect
analysis quantification process is also provided in the technical
report Post-Model Quantitative Analysis of Animal Avoidance Behavior
and Mitigation Effectiveness for the Gulf of Alaska Training (U.S.
Department of the Navy, 2014c; also available at: http://goaeis.com/Documents/SupplementalEISOEISDocumentsandReferences/SupportingTechnicalDocuments.aspx).

Take Request

The GOA DSEIS/OEIS considered all training activities proposed to
occur in the Study Area that have the potential to result in the MMPA
defined take of marine mammals. The stressors associated with these
activities included the following:
Acoustic (sonar and other active non-impulse sources,
explosives, swimmer defense airguns, weapons firing, launch and impact
noise, vessel noise, aircraft noise);
Energy (electromagnetic devices);
Physical disturbance or strikes (vessels, in-water
devices, military expended materials, seafloor devices);
Entanglement (fiber optic cables, guidance wires,
parachutes);
Ingestion (munitions, military expended materials other
than munitions); and
Secondary stressors (sediments and water quality).
The Navy determined, and NMFS agrees, that two stressors could
potentially result in the incidental taking of marine mammals from
training activities within the Study Area: (1) Non-impulsive stressors
(sonar and other active acoustic sources) and (2) impulsive stressors
(explosives). Non-impulsive and impulsive stressors have the potential
to result in incidental takes of marine mammals by harassment, injury,
or mortality.

Training Activities

A detailed analysis of effects due to marine mammal exposures to
impulsive and non-impulsive sources in the Study Area is presented in
Chapter 6 of the LOA application. Based on the model and post-model
analysis described in Chapter 6 of the LOA application, Table 12
summarizes the Navy's final take request for training activities for a
year (up to 2 exercises occurring over a 7-month period [April-
October]) and the summation over a 5-year period (up to 2 exercises
occurring over a 7-month period [April-October] for a total of 10
exercises).

[[Page 10000]]

Table 12--Summary of Annual and 5-Year Take Requests for GOA TMAA Training Activities
----------------------------------------------------------------------------------------------------------------
Training activities
-------------------------------------------------
MMPA Category Source Annual authorization 5-Year authorization
sought sought
----------------------------------------------------------------------------------------------------------------
Mortality............................ Explosives............. 0...................... 0.
Level A.............................. Sonar and other active 5 (Dall's porpoise only 25 (Dall's porpoise
acoustic sources; as shown in Table 13). only as shown in Table
explosives. 13).
Level B.............................. Sonar and other active 36,522 (Species 182,610 (Species
acoustic sources; specific data shown in specific data shown in
explosives. Table 13). Table 13).
----------------------------------------------------------------------------------------------------------------

Impulsive and Non-Impulsive Sources

Table 13 provides details on the Navy's final take request for
training activities by species from the acoustic effects modeling
estimates. Derivations of the numbers presented in Table 13 are
described in more detail within Chapter 6 of the LOA application. Level
A effects are only predicted to occur for Dall's porpoises. There are
no mortalities predicted for any of the proposed training activities.

Table 13--Species-Specific Take Requests From Modeling Estimates of Impulsive and Non-Impulsive Source Effects
for All Training Activities
----------------------------------------------------------------------------------------------------------------
Annual 5-Year
Species Stock ---------------------------------------------------------------
Level B Level A Level B Level A
----------------------------------------------------------------------------------------------------------------
North Pacific right whale..... Eastern North 7 0 35 0
Pacific.
Humpback whale................ Central North 129 0 645 0
Pacific.
Western North 10 0 50 0
Pacific.
Blue whale.................... Eastern North 95 0 475 0
Pacific.
Central North 0 0 0 0
Pacific.
Fin whale..................... Northeast 2,582 0 12,910 0
Pacific.
Sei whale..................... Eastern North 13 0 65 0
Pacific.
Minke whale................... Alaska.......... 87 0 435 0
Gray whale.................... Eastern North 0 0 0 0
Pacific.
Western North 0 0 0 0
Pacific.
Sperm whale................... North Pacific... 197 0 985 0
Killer whale.................. Alaska Resident. 564 0 2,820 0
Eastern North 53 0 265 0
Pacific
Offshore.
AT1 Transient... 1 0 5 0
GOA, Aleutian 144 0 720 0
Island, and
Bearing Sea
Transient.
Pacific white-sided dolphin... North Pacific... 1,963 0 9,815 0
Harbor porpoise............... Gulf of Alaska.. 5,484 0 27,420 0
Southeast Alaska 1,926 0 9,630 0
Dall's porpoise............... Alaska.......... 16,244 5 81,220 25
Cuvier's beaked whale......... Alaska.......... 2,544 0 12,720 0
Baird's beaked whale.......... Alaska.......... 401 0 2,005 0
Stejneger's beaked whale...... Alaska.......... 1,153 0 5,765 0
Steller sea lion.............. Eastern U.S..... 671 0 3,355 0
Western U.S..... 572 0 2,860 0
California sea lion........... U.S............. 5 0 25 0
Northern fur seal............. Eastern Pacific- 1,428 0 7,140 0
Alaska.
Northern elephant seal........ California 245 0 1,225 0
Breeding.
Harbor seal................... Aleutian Islands 0 0 0 0
Pribilof Islands 0 0 0 0
Bristol Bay..... 0 0 0 0
North Kodiak.... 1 0 5 0
South Kodiak.... 1 0 5 0
Prince William 2 0 10 0
Sound.
Cook Inlet/ 0 0 0 0
Shelikof.
Glacier Bay/Icy 0 0 0 0
Strait.
Lynn Canal/ 0 0 0 0
Stephens.
Harbor seal................... Sitka/Chatham... 0 0 0 0
Dixon/Cape 0 0 0 0
Decision.
Clarence Strait. 0 0 0 0
Ribbon seal................... Alaska.......... 0 0 0 0
---------------------------------------------------------------
Totals.................... ................ 36,522 5 182,610 25
----------------------------------------------------------------------------------------------------------------

Marine Mammal Habitat

The Navy's proposed training activities could potentially affect
marine mammal habitat through the introduction of sound into the water
column, impacts to the prey species of marine mammals, bottom
disturbance, or changes in water quality. Each of these components was
considered in the

[[Page 10001]]

GOA DSEIS/OEIS and was determined by the Navy to have no effect on
marine mammal habitat. Based on the information below and the
supporting information included in the GOA DSEIS/OEIS, NMFS has
preliminarily determined that the proposed training activities would
not have adverse or long-term impacts on marine mammal habitat.

Expected Effects on Habitat

Unless the sound source or explosive detonation is stationary and/
or continuous over a long duration in one area, the effects of the
introduction of sound into the environment are generally considered to
have a less severe impact on marine mammal habitat than the physical
alteration of the habitat. Acoustic exposures are not expected to
result in long-term physical alteration of the water column or bottom
topography, as the occurrences are of limited duration and are
intermittent in time. Surface vessels associated with the activities
are present in limited duration and are intermittent as they move
relatively rapidly through any given area. Most of the high-explosive
military expended materials would detonate at or near the water
surface. Only bottom-laid explosives are likely to affect bottom
substrate; habitat used for underwater detonations and seafloor device
placement would primarily be soft-bottom sediment. Once on the
seafloor, military expended material would likely be colonized by
benthic organisms because the materials would serve as anchor points in
the shifting bottom substrates, similar to a reef. The surface area of
bottom substrate affected would make up a very small percentage of the
total training area available in the Study Area.

Effects on Marine Mammal Prey

Invertebrates--Marine invertebrate distribution in the Study Area
is influenced by habitat, ocean currents, and water quality factors
such as temperature, salinity, and nutrient content (Levinton 2009).
The distribution of invertebrates is also influenced by their distance
from the equator (latitude); in general, the number of marine
invertebrate species increases toward the equator (Macpherson 2002).
The higher number of species (diversity) and abundance of marine
invertebrates in coastal habitats, compared with the open ocean, is a
result of more nutrient availability from terrestrial environments and
the variety of habitats and substrates found in coastal waters
(Levinton 2009).
The GOA is one of the world's most productive ocean regions and the
habitats associated with these cold and turbulent waters contain
identifiable collections of macrohabitats that sustain a multitude of
invertebrate species. Invertebrates in the GOA provide valuable links
in the food chain and perform ecosystem functions such as nutrient
processing. For humans, invertebrates contribute to economic, cultural,
and recreational activities in the GOA.
All marine invertebrate taxonomic groups are represented in the
Study Area. Major invertebrate phyla and the general zones they inhabit
in the Study Area are described in Chapter 3 of the 2011 GOA FEIS/OEIS.
Very little is known about sound detection and use of sound by
aquatic invertebrates (Budelmann 2010; Montgomery et al., 2006; Popper
et al., 2001). Organisms may detect sound by sensing either the
particle motion or pressure component of sound, or both. Aquatic
invertebrates probably do not detect pressure since many are generally
the same density as water and few, if any, have air cavities that would
function like the fish swim bladder in responding to pressure
(Budelmann, 2010; Popper et al., 2001). Many marine invertebrates,
however, have ciliated ``hair'' cells that may be sensitive to water
movements, such as those caused by currents or water particle motion
very close to a sound source (Budelmann, 2010; Mackie and Singla,
2003). These cilia may allow invertebrates to sense nearby prey or
predators or help with local navigation. Marine invertebrates may
produce and use sound in territorial behavior, to deter predators, to
find a mate, and to pursue courtship (Popper et al., 2001).
Both behavioral and auditory brainstem response studies suggest
that crustaceans may sense sounds up to three kilohertz (kHz), but best
sensitivity is likely below 200 Hz (Lovell et al., 2005; Lovell et al.,
2006; Goodall et al., 1990). Most cephalopods (e.g., octopus and squid)
likely sense low-frequency sound below 1,000 Hz, with best
sensitivities at lower frequencies (Budelmann, 2010; Mooney et al.,
2010; Packard et al., 1990). A few cephalopods may sense higher
frequencies up to 1,500 Hz (Hu et al., 2009). Squid did not respond to
toothed whale ultrasonic echolocation clicks at sound pressure levels
ranging from 199 to 226 dB re 1 [mu]Pa peak-to-peak, likely because
these clicks were outside of squid hearing range (Wilson et al., 2007).
However, squid exhibited alarm responses when exposed to broadband
sound from an approaching seismic airgun with received levels exceeding
145 to 150 dB re 1 [mu]Pa root mean square (McCauley et al., 2000b).
Little information is available on the potential impacts on marine
invertebrates of exposure to sonar, explosions, and other sound-
producing activities. It is expected that most marine invertebrates
would not sense mid- or high-frequency sounds, distant sounds, or
aircraft noise transmitted through the air-water interface. Most marine
invertebrates would not be close enough to intense sound sources, such
as some sonars, to potentially experience impacts to sensory
structures. Any marine invertebrate capable of sensing sound may alter
its behavior if exposed to non-impulsive sound, although it is unknown
if responses to non-impulsive sounds occur. Continuous noise, such as
from vessels, may contribute to masking of relevant environmental
sounds, such as reef noise. Because the distance over which most marine
invertebrates are expected to detect any sounds is limited and vessels
would be in transit, any sound exposures with the potential to cause
masking or behavioral responses would be brief and long-term impacts
are not expected. Although non-impulsive underwater sounds produced
during training activities may briefly impact individuals, intermittent
exposures to non-impulsive sounds are not expected to impact survival,
growth, recruitment, or reproduction of widespread marine invertebrate
populations.
Detonations associated with the Navy's GOA TMAA activities would
occur well offshore (the middle of the GOA TMAA is 140 nm offshore;
except for a point near Cape Cleare on Montague Island [12 nm away],
the nearest shoreline [Kenai Peninsula] is 24 nm north of the GOA TMAA
northern boundary). As water depth increases away from shore, benthic
invertebrates would be less likely to be impacted by detonations at or
near the surface. In addition, detonations near the surface would
release a portion of their explosive energy into the air, reducing the
explosive impacts in the water. Some marine invertebrates may be
sensitive to the low-frequency component of impulsive sound, and they
may exhibit startle reactions or temporary changes in swim speed in
response to an impulsive exposure. Because exposures are brief, limited
in number, and spread over a large area, no long-term impacts due to
startle reactions or short-term behavioral changes are expected.
Although individual marine invertebrates may be injured or killed
during an explosion or pile driving, no long-term impacts on

[[Page 10002]]

the survival, growth, recruitment, or reproduction of marine
invertebrate populations are expected.
Fish--Fish are not distributed uniformly throughout the Study Area,
but are closely associated with a variety of habitats. Some species
range across thousands of square miles while others have small home
ranges and restricted distributions (Helfman et al., 2009). The
movements of some open-ocean species may never overlap with coastal
fishes that spend their lives within several hundred feet (a few
hundred meters) of the shore. Even within a single fish species, the
distribution and specific habitats in which individuals occur may be
influenced by its developmental stage, size, sex, reproductive
condition, and other factors.
The distribution and abundance of fishes depends greatly on the
physical and biological factors of the marine ecosystem, such as
salinity, temperature, dissolved oxygen, population dynamics, predator
and prey interaction oscillations, seasonal movements, reproduction and
life cycles, and recruitment success (Helfman et al., 1997). A single
factor is rarely responsible for the distribution of fish species; more
often, a combination of factors is accountable. For example, open ocean
species optimize their growth, reproduction, and survival by tracking
gradients of temperature, oxygen, or salinity (Helfman et al., 1997).
Another major component in understanding species distribution is the
location of highly productive regions, such as frontal zones. These
areas concentrate various prey species and their predators, such as
tuna, and provide visual cues for the location of target species for
commercial fisheries (NMFS, 2001).
At least 383 species belonging to 84 families of marine and
anadromous fishes have been reported from the predominant ecosystems
found in the GOA TMAA. Detailed information on taxa presence,
distribution, and characteristics are provided in Chapter 3 of the 2011
GOA FEIS/OEIS.
All fish have two sensory systems to detect sound in the water: The
inner ear, which functions very much like the inner ear in other
vertebrates, and the lateral line, which consists of a series of
receptors along the fish's body (Popper, 2008). The inner ear generally
detects relatively higher-frequency sounds, while the lateral line
detects water motion at low frequencies (below a few hundred Hz)
(Hastings and Popper, 2005a). Although hearing capability data only
exist for fewer than 100 of the 32,000 fish species, current data
suggest that most species of fish detect sounds from 50 to 1,000 Hz,
with few fish hearing sounds above 4 kHz (Popper, 2008). It is believed
that most fish have their best hearing sensitivity from 100 to 400 Hz
(Popper, 2003b). Additionally, some clupeids (shad in the subfamily
Alosinae) possess ultrasonic hearing (i.e., able to detect sounds above
100,000 Hz) (Astrup, 1999). Permanent hearing loss, or permanent
threshold shift has not been documented in fish. The sensory hair cells
of the inner ear in fish can regenerate after they are damaged, unlike
in mammals where sensory hair cells loss is permanent (Lombarte et al.,
1993; Smith et al., 2006). As a consequence, any hearing loss in fish
may be as temporary as the timeframe required to repair or replace the
sensory cells that were damaged or destroyed (e.g., Smith et al.,
2006).
Potential direct injuries from non-impulsive sound sources, such as
sonar, are unlikely because of the relatively lower peak pressures and
slower rise times than potentially injurious sources such as
explosives. Non-impulsive sources also lack the strong shock waves
associated with an explosion. Therefore, direct injury is not likely to
occur from exposure to non-impulsive sources such as sonar, vessel
noise, or subsonic aircraft noise. Only a few fish species are able to
detect high-frequency sonar and could have behavioral reactions or
experience auditory masking during these activities. These effects are
expected to be transient and long-term consequences for the population
are not expected. MFAS is unlikely to impact fish species because most
species are unable to detect sounds in this frequency range and vessels
operating MFAS would be transiting an area (not stationary). While a
large number of fish species may be able to detect low-frequency sonar
and other active acoustic sources, low-frequency active usage is rare
and mostly conducted in deeper waters. Overall effects to fish from
non-impulsive sound sources would be localized and infrequent.
Physical effects from pressure waves generated by underwater sounds
(e.g. underwater explosions) could potentially affect fish within
proximity of training activities. In particular, the rapid oscillation
between high- and low-pressure peaks has the potential to burst the
swim bladders and other gas-containing organs of fish (Keevin and
Hemen, 1997). Sublethal effects, such as changes in behavior of fish,
have been observed in several occasions as a result of noise produced
by explosives (National Research Council of the National Academies,
2003; Wright, 1982). If an individual fish were repeatedly exposed to
sounds from underwater explosions that caused alterations in natural
behavioral patterns or physiological stress, these impacts could lead
to long-term consequences for the individual such as reduced survival,
growth, or reproductive capacity. However, the time scale of individual
explosions is very limited, and training exercises involving explosions
are dispersed in space and time. Consequently, repeated exposure of
individual fish to sounds from underwater explosions is not likely and
most acoustic effects are expected to be short-term and localized.
Long-term consequences for populations would not be expected.

Marine Mammal Avoidance

Marine mammals may be temporarily displaced from areas where Navy
training is occurring, but the area should be utilized again after the
activities have ceased. Avoidance of an area can help the animal avoid
further acoustic effects by avoiding or reducing further exposure. The
intermittent or short duration of many activities should prevent
animals from being exposed to stressors on a continuous basis (for the
GOA TMAA, training activities will not occur continuously throughout
the year, but rather, for a maximum of 21 days either once or twice
annually). In areas of repeated and frequent acoustic disturbance, some
animals may habituate or learn to tolerate the new baseline or
fluctuations in noise level. While some animals may not return to an
area, or may begin using an area differently due to training
activities, most animals are expected to return to their usual
locations and behavior.

Other Expected Effects

Other sources that may affect marine mammal habitat were considered
in the GOA DSEIS/OEIS and potentially include the introduction of fuel,
debris, ordnance, and chemical residues into the water column. The
majority of high-order explosions would occur at or above the surface
of the ocean, and would have no impacts on sediments and minimal
impacts on water quality. While disturbance or strike from an item
falling through the water column is possible, it is unlikely because
(1) objects sink slowly, (2) most projectiles are fired at targets (and
hit those targets), and (3) animals are generally widely dispersed
throughout the water column and over the Study Area. Chemical,
physical, or biological changes in sediment or water quality would not
be detectable. In the event of an ordnance failure, the energetic
materials it contained would remain mostly intact. The explosive
materials

[[Page 10003]]

in failed ordnance items and metal components from training would leach
slowly and would quickly disperse in the water column. Chemicals from
other explosives would not be introduced into the water column in large
amounts and all torpedoes would be recovered following training
activities, reducing the potential for chemical concentrations to reach
levels that can affect sediment quality, water quality, or benthic
habitats.

Preliminary Analysis and Negligible Impact Determination

Negligible impact is ``an impact resulting from the specified
activity that cannot be reasonably expected to, and is not reasonably
likely to, adversely affect the species or stock through effects on
annual rates of recruitment or survival'' (50 CFR 216.103). A
negligible impact finding is based on the lack of likely adverse
effects on annual rates of recruitment or survival (i.e., population-
level effects). An estimate of the number of takes, alone, is not
enough information on which to base an impact determination, as the
severity of harassment may vary greatly depending on the context and
duration of the behavioral response, many of which would not be
expected to have deleterious impacts on the fitness of any individuals.
In determining whether the expected takes will have a negligible
impact, in addition to considering estimates of the number of marine
mammals that might be ``taken,'' NMFS must consider other factors, such
as the likely nature of any responses (their intensity, duration,
etc.), the context of any responses (critical reproductive time or
location, migration, etc.), as well as the number and nature (e.g.,
severity) of estimated Level A harassment takes, the number of
estimated mortalities, and the status of the species. As a reminder,
the GOA TMAA training activities will not occur continuously throughout
the year, but rather, for a maximum of 21 days either once or twice
annually).
The Navy's specified activities have been described based on best
estimates of the maximum amount of sonar and other acoustic source use
or detonations that the Navy would conduct. There may be some
flexibility in that the exact number of hours, items, or detonations
may vary from year to year, but take totals are not authorized to
exceed the 5-year totals indicated in Tables 12-13. We base our
analysis and NID on the maximum number of takes authorized, although,
as stated before, the number of takes are only a part of the analysis,
which includes extensive qualitative consideration of other contextual
factors that influence the degree of impact of the takes on the
effected individuals. To avoid repetition, we provide some general
analysis immediately below that applies to all the species listed in
Tables 13, given that some of the anticipated effects (or lack thereof)
of the Navy's training activities on marine mammals are expected to be
relatively similar in nature. However, below that, we break our
analysis into species, or groups of species where relevant similarities
exist, to provide more specific information related to the anticipated
effects on individuals or where there is information about the status
or structure of any species that would lead to a differing assessment
of the effects on the population.
The Navy's take request is based on its model and post-model
analysis. In the discussions below, the ``acoustic analysis'' refers to
the Navy's modeling results and post-model analysis. The model
calculates sound energy propagation from sonar, other active acoustic
sources, and explosives during naval activities; the sound or impulse
received by animat dosimeters representing marine mammals distributed
in the area around the modeled activity; and whether the sound or
impulse received by a marine mammal exceeds the thresholds for effects.
The model estimates are then further analyzed to consider animal
avoidance and implementation of highly effective mitigation measures to
prevent Level A harassment, resulting in final estimates of effects due
to Navy training and testing. NMFS provided input to the Navy on this
process and the Navy's qualitative analysis is described in detail in
Chapter 6 of its LOA application (http://www.nmfs.noaa.gov/pr/permits/incidental/militry.htm).
Generally speaking, and especially with other factors being equal,
the Navy and NMFS anticipate more severe effects from takes resulting
from exposure to higher received levels (though this is in no way a
strictly linear relationship throughout species, individuals, or
circumstances) and less severe effects from takes resulting from
exposure to lower received levels. The requested number of Level B
takes does not equate to the number of individual animals the Navy
expects to harass (which is lower), but rather to the instances of take
(i.e., exposures above the Level B harassment threshold) that would
occur. Additionally, these instances may represent either a very brief
exposure (seconds) or, in some cases, longer durations of exposure
within a day. Depending on the location, duration, and frequency of
activities, along with the distribution and movement of marine mammals,
individual animals may be exposed to impulse or non-impulse sounds at
or above the Level B harassment threshold on multiple days. However,
the Navy is currently unable to estimate the number of individuals that
may be taken during training and testing activities. The model results
estimate the total number of takes that may occur to a smaller number
of individuals. While the model shows that an increased number of
exposures may take place due to an increase in events/activities and
ordnance, the types and severity of individual responses to training
and testing activities are not expected to change.

Behavioral Harassment

As discussed previously in this proposed rule, marine mammals can
respond to LF/MFAS/HFAS in many different ways, a subset of which
qualifies as behavioral harassment. As described in the proposed rule,
the Navy uses the behavioral response function to quantify the number
of behavioral responses that would qualify as Level B behavioral
harassment under the MMPA. As the statutory definition is currently
applied, a wide range of behavioral reactions may qualify as Level B
harassment under the MMPA, including but not limited to avoidance of
the sound source, temporary changes in vocalizations or dive patterns,
temporary avoidance of an area, or temporary disruption of feeding,
migrating, or reproductive behaviors.
Some of the lower level physiological stress responses discussed
earlier would also likely co-occur with the predicted harassments,
although these responses are more difficult to detect and fewer data
exist relating these responses to specific received levels of sound.
Level B takes, then, may have a stress-related physiological component
as well; however, we would not expect the Navy's generally short-term,
intermittent, and (in the case of sonar) transitory activities to
create conditions of long-term, continuous noise leading to long-term
physiological stress responses in marine mammals.
The estimates calculated using the behavioral response function do
not differentiate between the different types of potential reactions.
Nor do the estimates provide information regarding the potential
fitness or other biological consequences of the reactions on the
affected individuals. We therefore consider the available scientific
evidence to determine the likely nature of the modeled behavioral
responses and the potential fitness consequences for affected
individuals.

[[Page 10004]]

For LF/MFAS/HFAS use in the GOA TMAA, the Navy provided information
(Table 14) estimating the percentage of behavioral harassment that
would occur within the 6-dB bins (without considering mitigation or
avoidance). As mentioned above, an animal's exposure to a higher
received level is more likely to result in a behavioral response that
is more likely to adversely affect the health of the animal. As
illustrated below, the majority (including about 72 percent for the
most powerful ASW hull-mounted sonar, which is responsible for a large
portion of the sonar takes) of calculated takes from MFAS result from
exposures less than 156 dB. Less than 1 percent of the takes are
expected to result from exposures above 174 dB. Specifically, given a
range of behavioral responses that may be classified as Level B
harassment, to the degree that higher received levels are expected to
result in more severe behavioral responses, only a small percentage of
the anticipated Level B harassment from Navy activities might
necessarily be expected to potentially result in more severe responses,
especially when the distance from the source at which the levels below
are received is considered (see Table 14). Marine mammals are able to
discern the distance of a given sound source, and given other equal
factors (including received level), they have been reported to respond
more to sounds that are closer (DeRuiter et al., 2013). Further, the
estimated number of responses do not reflect either the duration or
context of those anticipated responses, some of which will be of very
short duration, and other factors should be considered when predicting
how the estimated takes may affect individual fitness. A recent study
by Moore and Barlow (2013) emphasizes the importance of context (e.g.,
behavioral state of the animals, distance from the sound source, etc.)
in evaluating behavioral responses of marine mammals to acoustic
sources.

Table 14--Non-Impulsive Ranges in 6-dB bins and Percentage of Behavioral Harassments
--------------------------------------------------------------------------------------------------------------------------------------------------------
Sonar bin MF1 (e.g., SQS-53; ASW Sonar bin MF4 (e.g., AQS-22; ASW Sonar Bin MF5 (e.g., SSQ-62; ASW
hull mounted sonar) dipping sonar) sonobuoy)
-----------------------------------------------------------------------------------------------------------------
Percentage of Percentage of Percentage of
Received level Distance at which behavioral Distance at which behavioral Distance at which behavioral
levels occur harassments levels occur harassments levels occur harassments
within radius of occurring at within radius of occurring at within radius of occurring at
source (m) given levels source (m) given levels source (m) given levels
--------------------------------------------------------------------------------------------------------------------------------------------------------
Low Frequency Cetaceans
--------------------------------------------------------------------------------------------------------------------------------------------------------
120 <= SPL <126....................... 178,750-156,450 0.00 100,000-92,200 0.00 22,800-15,650 0.00
126 <= SPL <132....................... 156,450-147,500 0.00 92,200-55,050 0.11 15,650-11,850 0.05
132 <= SPL <138....................... 147,500-103,700 0.21 55,050-46,550 1.08 11,850-6,950 2.84
138 <= SPL <144....................... 103,700-97,950 0.33 46,550-15,150 35.69 6,950-3,600 16.04
144 <= SPL <150....................... 97,950-55,050 13.73 15,150-5,900 26.40 3,600-1,700 33.63
150 <= SPL <156....................... 55,050-49,900 5.28 5,900-2,700 17.43 1,700-250 44.12
156 <= SPL <162....................... 49,900-10,700 72.62 2,700-1,500 9.99 250-100 2.56
162 <= SPL <168....................... 10,700-4,200 6.13 1,500-200 9.07 100-<50 0.76
168 <= SPL <174....................... 4,200-1,850 1.32 200-100 0.18 <50 0.00
174 <= SPL <180....................... 1,850-850 0.30 100-<50 0.05 <50 0.00
180 <= SPL <186....................... 850-400 0.07 <50 0.00 <50 0.00
186 <= SPL <192....................... 400-200 0.01 <50 0.00 <50 0.00
192 <= SPL <198....................... 200-100 0.00 <50 0.00 <50 0.00
--------------------------------------------------------------------------------------------------------------------------------------------------------
Mid Frequency Cetaceans
--------------------------------------------------------------------------------------------------------------------------------------------------------
120 <= SPL <126....................... 179,400-156,450 0.00 100,000-92,200 0.00 23,413-16,125 0.00
126 <= SPL <132....................... 156,450-147,500 0.00 92,200-55,050 0.11 16,125-11,500 0.06
132 <= SPL <138....................... 147,500-103,750 0.21 55,050-46,550 1.08 11,500-6,738 2.56
138 <= SPL <144....................... 103,750-97,950 0.33 46,550-15,150 35.69 6,738-3,825 13.35
144 <= SPL <150....................... 97,950-55,900 13.36 15,150-5,900 26.40 3,825-1,713 37.37
150 <= SPL <156....................... 55,900-49,900 6.12 5,900-2,700 17.43 1,713-250 42.85
156 <= SPL <162....................... 49,900-11,450 71.18 2,700-1,500 9.99 250-150 1.87
162 <= SPL <168....................... 11,450-4,350 7.01 1,500-200 9.07 150-<50 1.93
168 <= SPL <174....................... 4,350-1,850 1.42 200-100 0.18 <50 0.00
174 <= SPL <180....................... 1,850-850 0.29 100-<50 0.05 <50 0.00
180 <= SPL <186....................... 850-400 0.07 <50 0.00 <50 0.00
186 <= SPL <192....................... 400-200 0.01 <50 0.00 <50 0.00
192 <= SPL <198....................... 200-100 0.00 <50 0.00 <50 0.00
--------------------------------------------------------------------------------------------------------------------------------------------------------
Notes: (1) ASW = anti-submarine warfare, m = meters, SPL = sound pressure level; (2) Odontocete behavioral response function is also used for high-
frequency cetaceans, phocid seals, otariid seals and sea lions, and sea otters.

Although the Navy has been monitoring to discern the effects of LF/
MFAS/HFAS on marine mammals since 2006, and research on the effects of
MFAS is advancing, our understanding of exactly how marine mammals in
the Study Area will respond to LF/MFAS/HFAS is still improving. The
Navy has submitted more than 80 reports, including Major Exercise
Reports, Annual Exercise Reports, and Monitoring Reports, documenting
hundreds of thousands of marine mammals across Navy range complexes,
and there are only two instances of overt behavioral disturbances that
have been observed. One cannot conclude from these results that marine
mammals were not harassed from MFAS/HFAS, as a portion of animals
within the area of concern were not seen (especially those more
cryptic, deep-diving species, such as beaked whales or Kogia spp.), the
full series of behaviors that would more accurately show an important
change is not typically seen (i.e., only the surface behaviors are
observed), and some of the non-biologist watchstanders might not be
well-qualified to characterize behaviors. However, one can say that the
animals that were observed did not respond in any of the obviously more
severe ways, such as panic, aggression, or anti-predator response.

[[Page 10005]]

Diel Cycle

As noted previously, many animals perform vital functions, such as
feeding, resting, traveling, and socializing on a diel cycle (24-hour
cycle). Behavioral reactions to noise exposure (when taking place in a
biologically important context, such as disruption of critical life
functions, displacement, or avoidance of important habitat) are more
likely to be significant if they last more than one diel cycle or recur
on subsequent days (Southall et al., 2007). Consequently, a behavioral
response lasting less than one day and not recurring on subsequent days
is not considered severe unless it could directly affect reproduction
or survival (Southall et al., 2007). Note that there is a difference
between multiple-day substantive behavioral reactions and multiple-day
anthropogenic activities. For example, just because an at-sea exercise
lasts for multiple days does not necessarily mean that individual
animals are either exposed to those exercises for multiple days or,
further, exposed in a manner resulting in a sustained multiple day
substantive behavioral response. Large multi-day Navy exercises, such
as those proposed in the GOA TMAA, typically include vessels that are
continuously moving at speeds typically 10-15 knots, or higher, and
likely cover large areas that are relatively far from shore, in
addition to the fact that marine mammals are moving as well, which
would make it unlikely that the same animal could remain in the
immediate vicinity of the ship for the entire duration of the exercise.
Additionally, the Navy does not necessarily operate active sonar the
entire time during an exercise. While it is certainly possible that
these sorts of exercises could overlap with individual marine mammals
multiple days in a row at levels above those anticipated to result in a
take, because of the factors mentioned above, it is considered unlikely
for the majority of takes. It does not mean that a behavioral response
is necessarily sustained for multiple days, but instead necessitates
the consideration of likely duration and context to assess any effects
on the individual's fitness.
Durations for non-impulsive activities utilizing tactical sonar
sources vary and are fully described in Appendix A of the GOA DSEIS/
OEIS. ASW training exercises using MFAS/HFAS proposed for the GOA TMAA
generally last for 2-16 hours, and may have intervals of non-activity
in between. Because of the need to train in a large variety of
situations (in the case of the GOA TMAA, complex bathymetric and
oceanographic conditions include a continental shelf, submarine
canyons, seamounts, and fresh water infusions from multiple sources),
the Navy does not typically conduct successive ASW exercises in the
same locations. Given the average length of ASW exercises (times of
continuous sonar use) and typical vessel speed, combined with the fact
that the majority of the cetaceans in the GOA TMAA Study Area would not
likely remain in an area for successive days, it is unlikely that an
animal would be exposed to MFAS/HFAS at levels likely to result in a
substantive response that would then be carried on for more than one
day or on successive days.
With the exception of SINKEXs, the planned explosive exercises for
the GOA TMAA are of a short duration (1-6 hours). Although explosive
exercises may sometimes be conducted in the same general areas
repeatedly, because of their short duration and the fact that they are
in the open ocean and animals can easily move away, it is similarly
unlikely that animals would be exposed for long, continuous amounts of
time. Although SINKEXs may last for up to 48 hrs, only two are planned
annually for the GOA TMAA training activities, they are stationary and
conducted in deep, open water (where fewer marine mammals would
typically be expected to be randomly encountered), and they have a
rigorous monitoring and shutdown procedures, all of which make it
unlikely that individuals would be exposed to the exercise for extended
periods or on consecutive days.

TTS

As mentioned previously, TTS can last from a few minutes to days,
be of varying degree, and occur across various frequency bandwidths,
all of which determine the severity of the impacts on the affected
individual, which can range from minor to more severe. The TTS
sustained by an animal is primarily classified by three
characteristics:
1. Frequency--Available data (of mid-frequency hearing specialists
exposed to mid- or high-frequency sounds; Southall et al., 2007)
suggest that most TTS occurs in the frequency range of the source up to
one octave higher than the source (with the maximum TTS at \1/2\ octave
above). The more powerful MF sources used have center frequencies
between 3.5 and 8 kHz and the other unidentified MF sources are, by
definition, less than 10 kHz, which suggests that TTS induced by any of
these MF sources would be in a frequency band somewhere between
approximately 2 and 20 kHz. There are fewer hours of HF source use and
the sounds would attenuate more quickly, plus they have lower source
levels, but if an animal were to incur TTS from these sources, it would
cover a higher frequency range (sources are between 20 and 100 kHz,
which means that TTS could range up to 200 kHz; however, HF systems are
typically used less frequently and for shorter time periods than
surface ship and aircraft MF systems, so TTS from these sources is even
less likely). TTS from explosives would be broadband. Vocalization data
for each species, which would inform how TTS might specifically
interfere with communications with conspecifics, was provided in the
LOA application.
2. Degree of the shift (i.e., by how many dB the sensitivity of the
hearing is reduced)--Generally, both the degree of TTS and the duration
of TTS will be greater if the marine mammal is exposed to a higher
level of energy (which would occur when the peak dB level is higher or
the duration is longer). The threshold for the onset of TTS was
discussed previously in this proposed rule. An animal would have to
approach closer to the source or remain in the vicinity of the sound
source appreciably longer to increase the received SEL, which would be
difficult considering the Lookouts and the nominal speed of an active
sonar vessel (10-15 knots). In the TTS studies (see Threshold Shift
section), some using exposures of almost an hour in duration or up to
217 SEL, most of the TTS induced was 15 dB or less, though Finneran et
al. (2007) induced 43 dB of TTS with a 64-second exposure to a 20 kHz
source. However, MFAS emits a ping typically every 50 seconds, and
incurring those levels of TTS is highly unlikely.
3. Duration of TTS (recovery time)--In the TTS laboratory studies
(see Threshold Shift section), some using exposures of almost an hour
in duration or up to 217 SEL, almost all individuals recovered within 1
day (or less, often in minutes), although in one study (Finneran et
al., 2007), recovery took 4 days.
Based on the range of degree and duration of TTS reportedly induced
by exposures to non-pulse sounds of energy higher than that to which
free-swimming marine mammals in the field are likely to be exposed
during MFAS/HFAS training exercises in the GOA TMAA, it is unlikely
that marine mammals would ever sustain a TTS from MFAS that alters
their sensitivity by more than 20 dB for more than a few days (and any
incident of TTS would likely be far less severe due to the short
duration of the majority of the exercises and the speed of a typical
vessel). Also, for the same reasons discussed in the Diel Cycle
section, and because of the

[[Page 10006]]

short distance within which animals would need to approach the sound
source, it is unlikely that animals would be exposed to the levels
necessary to induce TTS in subsequent time periods such that their
recovery is impeded. Additionally, though the frequency range of TTS
that marine mammals might sustain would overlap with some of the
frequency ranges of their vocalization types, the frequency range of
TTS from MFAS (the source from which TTS would most likely be sustained
because the higher source level and slower attenuation make it more
likely that an animal would be exposed to a higher received level)
would not usually span the entire frequency range of one vocalization
type, much less span all types of vocalizations or other critical
auditory cues. If impaired, marine mammals would typically be aware of
their impairment and are sometimes able to implement behaviors to
compensate (see Acoustic Masking or Communication Impairment section),
though these compensations may incur energetic costs.

Acoustic Masking or Communication Impairment

Masking only occurs during the time of the signal (and potential
secondary arrivals of indirect rays), versus TTS, which continues
beyond the duration of the signal. Standard MFAS typically pings every
50 seconds for hull-mounted sources. For the sources for which we know
the pulse length, most are significantly shorter than hull-mounted
active sonar, on the order of several microseconds to tens of
microseconds. For hull-mounted active sonar, though some of the
vocalizations that marine mammals make are less than one second long,
there is only a 1 in 50 chance that they would occur exactly when the
ping was received, and when vocalizations are longer than one second,
only parts of them are masked. Alternately, when the pulses are only
several microseconds long, the majority of most animals' vocalizations
would not be masked. Masking effects from MFAS/HFAS are expected to be
minimal. If masking or communication impairment were to occur briefly,
it would be in the frequency range of MFAS, which overlaps with some
marine mammal vocalizations; however, it would likely not mask the
entirety of any particular vocalization, communication series, or other
critical auditory cue, because the signal length, frequency, and duty
cycle of the MFAS/HFAS signal does not perfectly mimic the
characteristics of any marine mammal's vocalizations. The other sources
used in Navy training and testing, many of either higher frequencies
(meaning that the sounds generated attenuate even closer to the source)
or lower amounts of operation, are similarly not expected to result in
masking.

PTS, Injury, or Mortality

NMFS believes that many marine mammals would deliberately avoid
exposing themselves to the received levels of active sonar necessary to
induce injury by moving away from or at least modifying their path to
avoid a close approach. Additionally, in the unlikely event that an
animal approaches the sonar vessel at a close distance, NMFS believes
that the mitigation measures (i.e., shutdown/powerdown zones for MFAS/
HFAS) would typically ensure that animals would not be exposed to
injurious levels of sound. As discussed previously, the Navy utilizes
both aerial (when available) and passive acoustic monitoring (during
all ASW exercises) in addition to watchstanders on vessels to detect
marine mammals for mitigation implementation.
If a marine mammal is able to approach a surface vessel within the
distance necessary to incur PTS, the likely speed of the vessel
(nominal 10-15 knots) would make it very difficult for the animal to
remain in range long enough to accumulate enough energy to result in
more than a mild case of PTS. As mentioned previously and in relation
to TTS, the likely consequences to the health of an individual that
incurs PTS can range from mild to more serious dependent upon the
degree of PTS and the frequency band it is in, and many animals are
able to compensate for the shift, although it may include energetic
costs. Only 5 Level A (PTS) takes per year are predicted from GOA
training activities, and these are all Dall's porpoise--not large whale
species or beaked whales. We also assume that the acoustic exposures
sufficient to trigger onset PTS (or TTS) would be accompanied by
physiological stress responses, although the sound characteristics that
correlate with specific stress responses in marine mammals are poorly
understood. As discussed above for Behavioral Harassment, we would not
expect the Navy's generally short-term, intermittent, and (in the case
of sonar) transitory activities to create conditions of long-term,
continuous noise leading to long-term physiological stress responses in
marine mammals. No other injurious takes or mortality are predicted. As
discussed previously, marine mammals (especially beaked whales) could
potentially respond to MFAS at a received level lower than the injury
threshold in a manner that indirectly results in the animals stranding.
The exact mechanism of this potential response, behavioral or
physiological, is not known. When naval exercises have been associated
with strandings in the past, it has typically been when three or more
vessels are operating simultaneously, in the presence of a strong
surface duct, and in areas of constricted channels, semi-enclosed
areas, and/or steep bathymetry. While these features certainly do not
define the only factors that can contribute to a stranding, and while
they need not all be present in their aggregate to increase the
likelihood of a stranding, it is worth noting that they are not all
present in the GOA TMAA, which only has a strong surface duct present
during the winter, and does not have bathymetry or constricted channels
of the type that have been present in the sonar associated strandings.
When this is combined with consideration of the number of hours of
active sonar training that will be conducted and the total duration of
all training exercises (a maximum of 21 days once or twice a year), we
believe that the probability is small that this will occur. Lastly, an
active sonar shutdown protocol for strandings involving live animals
milling in the water minimizes the chances that these types of events
turn into mortalities.
As stated previously, there have been no recorded Navy vessel
strikes of any marine mammals during training in the GOA Study Area to
date, nor were takes by injury or mortality resulting from vessel
strike predicted in the Navy's analysis.

Group and Species-Specific Analysis

Predicted effects on marine mammals from exposures to sonar and
other active acoustic sources and explosions during annual training
activities are shown in Table 13. The vast majority of predicted
exposures (greater than 99 percent) are expected to be Level B
harassment (non-injurious TTS and behavioral reactions) from sonar and
other active acoustic sources at relatively low received levels (Table
14). The acoustic analysis predicts the majority of marine mammal
species in the Study Area would not be exposed to explosive (impulsive)
sources associated with training activities. Only Dall's porpoise is
predicted to have Level B (TTS) exposures resulting from explosives,
and only a limited number (5) of Dall's porpoise are expected to have
injurious take (PTS) resulting from sonar and other active acoustic
sources and

[[Page 10007]]

explosions. There are no lethal takes predicted for any marine mammal
species for the GOA activities.
The analysis below may in some cases (e.g., mysticetes, porpoises,
pinnipeds) address species collectively if they occupy the same
functional hearing group (i.e., low-, mid-, and high-frequency
cetaceans and pinnipeds in water), have similar hearing capabilities,
and/or are known to generally behaviorally respond similarly to
acoustic stressors. Where there are meaningful differences between
species or stocks in anticipated individual responses to activities,
impact of expected take on the population due to differences in
population status, or impacts on habitat, they will either be described
within the section or the species will be included as a separate sub-
section.
Mysticetes--The Navy's acoustic analysis predicts that 2,923
instances of Level B harassmant of mysticete whales may occur in the
Study Area each year from sonar and other active acoustic sources
during training activities. Annual species-specific take estimates are
as follows: 7 North Pacific right whales (Eastern North Pacific stock),
139 humpback whales (Central North Pacific and Western North Pacific
stocks), 95 blue whales (Eastern North Pacific stock), 2,582 fin whales
(Northeast Pacific stock), 13 sei whales (Eastern North Pacific stock),
and 87 minke whales (Alaska stock). Of these species, humpback, blue,
fin, sei, and North Pacific right whales are listed as endangered under
the ESA and depleted under the MMPA. NMFS is currently engaged in an
internal Section 7 consultation under the ESA and the outcome of that
consultation will further inform our final decision. Based on the
distribution information presented in the LOA application, it is highly
unlikely that gray whales would be encountered in the Study Area during
events involving use of sonar and other active acoustic sources. The
acoustic analysis did not predict any takes of gray whales and NMFS is
not authorizing any takes of this species.
Generally, these represent a limited number of takes relative to
population estimates for most mysticete stocks in the Study Area (Table
6). When the numbers of behavioral takes are compared to the estimated
stock abundance and if one assumes that each take happens to a separate
animal, less than approximately 20 percent of each of these stocks
(with the exception of the Northeast Pacific stock of fin whale and the
Alaska stock of minke whale for which there currently are no reliable
population estimates because only portions of the stocks' range have
been surveyed [Muto and Angliss, 2015]) would be behaviorally harassed
during the course of a year. Because the estimates given above
represent the total number of exposures and not necessarily the number
of individuals exposed, it is more likely that fewer individuals would
be taken, but a subset would be taken more than one time per year. In
the ocean, the use of sonar and other active acoustic sources is
transient and is unlikely to repeatedly expose the same population of
animals over a short period.
Level B harassment takes are anticipated to be in the form of TTS
and behavioral reactions and no injurious takes of North Pacific right,
humpback, blue, fin, minke, or sei whales from sonar and other active
acoustic stressors or explosives are expected. The majority of acoustic
effects to mysticetes from sonar and other active sound sources during
training activities would be primarily from anti-submarine warfare
events involving surface ships and hull mounted sonar. Research and
observations show that if mysticetes are exposed to sonar or other
active acoustic sources they may react in a number of ways depending on
the characteristics of the sound source, their experience with the
sound source, and whether they are migrating or on seasonal grounds
(i.e., breeding or feeding). Reactions may include alerting, breaking
off feeding dives and surfacing, diving or swimming away, or no
response at all (Richardson, 1995; Nowacek, 2007; Southall et al.,
2007; Finneran and Jenkins, 2012). Richardson et al. (1995) noted that
avoidance (temporary displacement of an individual from an area)
reactions are the most obvious manifestations of disturbance in marine
mammals. Avoidance is qualitatively different from the startle or
flight response, but also differs in the magnitude of the response
(i.e., directed movement, rate of travel, etc.). Oftentimes avoidance
is temporary, and animals return to the area once the noise has ceased.
Additionally, migrating animals may ignore a sound source, or divert
around the source if it is in their path.
Specific to U.S. Navy systems using low frequency sound, studies
were undertaken in 1997-98 pursuant to the Navy's Low Frequency Sound
Scientific Research Program. These studies found only short-term
responses to low frequency sound by mysticetes (fin, blue, and humpback
whales) including changes in vocal activity and avoidance of the source
vessel (Clark, 2001; Miller et al., 2000; Croll et al., 2001; Fristrup
et al., 2003; Nowacek et al., 2007). Baleen whales exposed to moderate
low-frequency signals demonstrated no variation in foraging activity
(Croll et al., 2001). Low-frequency signals of the Acoustic Thermometry
of Ocean Climate sound source were not found to affect dive times of
humpback whales in Hawaiian waters (Frankel and Clark, 2000).
Specific to mid-frequency sound, studies by Melc[oacute]n et al.
(2012) in the Southern California Bight found that the likelihood of
blue whale low-frequency calling (usually associated with feeding
behavior) decreased with an increased level of MFAS, beginning at a SPL
of approximately 110-120 dB re 1 [mu]Pa. However, it is not known
whether the lower rates of calling actually indicated a reduction in
feeding behavior or social contact since the study used data from
remotely deployed, passive acoustic monitoring buoys. Results from the
2010-2011 field season of an ongoing behavioral response study in
Southern California waters indicated that in some cases and at low
received levels, tagged blue whales responded to MFAS but that those
responses were mild and there was a quick return to their baseline
activity (Southall et al., 2011; Southall et al., 2012b). Blue whales
responded to a mid-frequency sound source, with a source level between
160 and 210 dB re 1 [mu]Pa at 1 m and a received sound level up to 160
dB re 1 [mu]Pa, by exhibiting generalized avoidance responses and
changes to dive behavior during the exposure experiments (CEE)
(Goldbogen et al., 2013). However, reactions were not consistent across
individuals based on received sound levels alone, and likely were the
result of a complex interaction between sound exposure factors such as
proximity to sound source and sound type (MFAS simulation vs. pseudo-
random noise), environmental conditions, and behavioral state. Surface
feeding whales did not show a change in behavior during CEEs, but deep
feeding and non-feeding whales showed temporary reactions that quickly
abated after sound exposure. Distances of the sound source from the
whales during CEEs were sometimes less than a mile. Blue whales have
been documented exhibiting a range of foraging strategies for
maximizing feeding dependent on the density of their prey at a given
location (Goldbogen et al., 2015), so it may be that a temporary
behavioral reaction or avoidance of a location where feeding was
occurring is not meaningful to the life history of an animal. The
preliminary findings from Goldbogen et al. (2013) and Melc[oacute]n et
al. (2012) are generally consistent with

[[Page 10008]]

the Navy's criteria and thresholds for predicting behavioral effects to
mysticetes from sonar and other active acoustic sources used in the
quantitative acoustic effects analysis for GOA. The Navy's behavioral
response function predicts the probability of a behavioral response
that rises to a Level B take for individuals exposed to a received SPL
of 120 dB re 1 [mu]Pa or greater, with an increasing probability of
reaction with increased received level as demonstrated in Melc[oacute]n
et al. (2012).
High-frequency systems are notably outside of mysticetes' ideal
hearing and vocalization range and it is unlikely that they would cause
a significant behavioral reaction.
Most Level B harassments to mysticetes from sonar in the Study Area
would result from received levels less than 156 dB SPL. Therefore, the
majority of Level B takes are expected to be in the form of milder
responses (i.e., lower-level exposures that still rise to the level of
take, but would likely be less severe in the range of responses that
qualify as take) of a generally short duration. As mentioned earlier in
this section, we anticipate more severe effects from takes when animals
are exposed to higher received levels. Most low-frequency (mysticetes)
cetaceans observed in studies usually avoided sound sources at levels
of less than or equal to 160 dB re 1[mu]Pa. Occasional milder
behavioral reactions are unlikely to cause long-term consequences for
individual animals or populations. Even if sound exposure were to be
concentrated in a relatively small geographic area over a long period
of time (e.g., days or weeks during major training exercises), we would
expect that some individual whales would avoid areas where exposures to
acoustic stressors are at higher levels. For example, Goldbogen et al.
(2013) indicated some horizontal displacement of deep foraging blue
whales in response to simulated MFA sonar. Given these animal's
mobility and large ranges, we would expect these individuals to
temporarily select alternative foraging sites nearby until the exposure
levels in their initially selected foraging area have decreased.
Therefore, even temporary displacement from initially selected foraging
habitat is not expected to impact the fitness of any individual animals
because we would expect equivalent foraging to be available in close
proximity. Because we do not expect any fitness consequences from any
individual animals, we do not expect any population level effects from
these behavioral responses.
As explained above, recovery from a threshold shift (TTS) can take
a few minutes to a few days, depending on the exposure duration, sound
exposure level, and the magnitude of the initial shift, with larger
threshold shifts and longer exposure durations requiring longer
recovery times (Finneran et al., 2005; Finneran and Schlundt, 2010;
Mooney et al., 2009a; Mooney et al., 2009b). However, large threshold
shifts are not anticipated for these activities because of the
unlikelihood that animals will remain within the ensonified area (due
to the short duration of the majority of exercises, the speed of the
vessels, and the short distance within which the animal would need to
approach the sound source) at high levels for the duration necessary to
induce larger threshold shifts. Threshold shifts do not necessarily
affect all hearing frequencies equally, so some threshold shifts may
not interfere with an animal's hearing of biologically relevant sounds.
Furthermore, the implementation of mitigation and the sightability of
mysticetes (due to their large size) reduces the potential for a
significant behavioral reaction or a threshold shift to occur.
Overall, the number of predicted behavioral reactions is low and
occasional behavioral reactions are unlikely to cause long-term
consequences for individual animals or populations. This assessment of
long-term consequences is based in part on findings from ocean areas
where the Navy has been intensively training and testing with sonar and
other active acoustic sources for decades. While there are many factors
such as the end of large-scale commercial whaling complicating any
analysis, there is no data suggesting any long-term consequences to
mysticetes from exposure to sonar and other active acoustic sources. On
the contrary, there are findings suggesting mysticete populations are
increasing in the two primary locations (Southern California and
Hawaii) where the Navy's most intensively used range complexes are
located. These findings include: (1) Calambokidis et al. (2009b)
indicating a significant upward trend in abundance of for blue whales
in Southern California; (2) the recovery of gray whales that migrate
through the Navy's SOCAL Range Complex twice a year; (3) work by Moore
and Barlow (2011) indicating evidence of increasing fin whale abundance
in the California Current area, which includes the SOCAL Range Complex;
(4) the range expansion and increasing presence of Bryde's whales south
of Point Conception in Southern California (Kerosky et al. 2012); and
(5) the ocean area contained within the Hawaii Range Complex continuing
to function as a critical breeding, calving, and nursing area to the
point at which the overall humpback whale population in the North
Pacific is now greater than some prior estimates of pre-whaling
abundance (Barlow et al., 2011). The implementation of mitigation and
the sightability of mysticetes (due to their large size) reduces the
potential for a significant behavioral reaction or a threshold shift to
occur. Furthermore, there is no designated critical habitat for
mysticetes in the Study Area. As discussed in the Consideration of
Time/Area Limitations section of this rule, review of the NMFS-
identified feeding and migration areas showed there is only minimal (<1
percent) spatial overlap with the GOA TMAA and the North Pacific right
whale feeding area southeast of Kodiak Island and minimal (<1 percent)
spatial overlap with a small portion of the gray whale migration area
offshore of Kenai Peninsula (Ferguson et al., 2015b). Those areas of
overlap at the corners of the GOA TMAA are very unlikely to have any
Navy training activity. Further, the grey whale migration area is only
applicable in the early spring and late fall, while training activities
are proposed for May to October (with June/July the main months of
training, historically). Therefore, it is very unlikely there would be
an effect to feeding or migrating activities if right whales or gray
whales were present. Additionally, appropriate mitigation measures (as
detailed in the Mitigation section above) would be implemented for any
detected marine mammals and thus further reducing the potential for the
feeding or migration activities to be affected. The Navy proposes to
monitor use of active sonar within the North Pacific right whale
feeding area and gray whale migration areas, to the extent that active
sonar training does occur in these areas, and to report that use to
NMFS in classified annual reports (see Proposed Reporting) to inform
future adaptive management of activities within the GOA TMAA.
Consequently, the GOA TMAA activities are not expected to adversely
impact rates of recruitment or survival of mysticete whales.
Sperm Whales--The Navy's acoustic analysis indicates that 197
instances of Level B harassment of sperm whales (North Pacific stock;
currently there are no reliable abundance estimates for this stock
[Muto and Angliss, 2015]) may occur in the Study Area each year from
sonar or other active acoustic stressors during training activities.
Sperm whales are listed as endangered under the ESA

[[Page 10009]]

and depleted under the MMPA. NMFS is currently engaged in an internal
Section 7 consultation under the ESA and the outcome of that
consultation will further inform our final decision. These Level B
takes are anticipated to be in the form of TTS and behavioral reactions
and no injurious takes of sperm whales from sonar and other active
acoustic stressors or explosives are requested or proposed for
authorization. Sperm whales have shown resilience to acoustic and human
disturbance, although they may react to sound sources and activities
within a few kilometers. Sperm whales that are exposed to activities
that involve the use of sonar and other active acoustic sources may
alert, ignore the stimulus, avoid the area by swimming away or diving,
or display aggressive behavior (Richardson, 1995; Nowacek, 2007;
Southall et al., 2007; Finneran and Jenkins, 2012). Some (but not all)
sperm whale vocalizations might overlap with the MFAS/HFAS TTS
frequency range, which could temporarily decrease an animal's
sensitivity to the calls of conspecifics or returning echolocation
signals. However, as noted previously, NMFS does not anticipate TTS of
a long duration or severe degree to occur as a result of exposure to
MFAS/HFAS. Recovery from a threshold shift (TTS) can take a few minutes
to a few days, depending on the exposure duration, sound exposure
level, and the magnitude of the initial shift, with larger threshold
shifts and longer exposure durations requiring longer recovery times
(Finneran et al., 2005; Mooney et al., 2009a; Mooney et al., 2009b;
Finneran and Schlundt, 2010). Large threshold shifts are not
anticipated for these activities because of the unlikelihood that
animals will remain within the ensonified area (due to the short
duration of the majority of exercises, the speed of the vessels, and
the short distance within which the animal would need to approach the
sound source) at high levels for the duration necessary to induce
larger threshold shifts. Threshold shifts do not necessarily affect all
hearing frequencies equally, so some threshold shifts may not interfere
with an animal's hearing of biologically relevant sounds. No sperm
whales are predicted to be exposed to MFAS/HFAS sound levels associated
with PTS or injury.
The majority of Level B takes are expected to be in the form of
mild responses (low-level exposures) and of a generally short duration.
Relative to the population size, this activity is anticipated to result
only in a limited number of Level B harassment takes. Because the
estimates given above represent the total number of exposures and not
necessarily the number of individuals exposed, it is more likely that
fewer individuals would be taken, but a subset would be taken more than
one time per year. In the ocean, the use of sonar and other active
acoustic sources is transient and is unlikely to repeatedly expose the
same population of animals over a short period. Overall, the number of
predicted behavioral reactions are unlikely to cause long-term
consequences for individual animals or populations. The GOA activities
are not expected to occur in an area/time of specific importance for
reproductive, feeding, or other known critical behaviors for sperm
whales, and there is no designated critical habitat in the Study Area.
Consequently, the activities are not expected to adversely impact
annual rates of recruitment or survival of sperm whales.
Dolphins and Small Whales--The Navy's acoustic analysis predicts
the following instances of Level B harassment of delphinids (dolphins
and small whales) each year from sonar and other active acoustic
sources associated with training activities in the Study Area: 762
killer whales (Alaska Resident; Eastern North Pacific Offshore; AT1
Transient; and GOA, Aleutian Island, and Bearing Sea Transient stocks)
and 1,963 Pacific white-sided dolphins (North Pacific stock). These
represent a limited number of takes relative to population estimates
for delphinid stocks in the Study Area (Table 6). When the numbers of
behavioral takes are compared to the estimated stock abundance and if
one assumes that each take happens to a separate animal, less than 25
percent of each of the killer whale stocks and less than 8 percent of
the North Pacific stock of Pacific white-sided dolphin would be
behaviorally harassed during the course of a year. More likely,
slightly fewer individuals would be harassed, but a subset would be
harassed more than one time during the course of the year.
All of these takes are anticipated to be in the form of behavioral
harassment (TTS and behavioral reaction) and no injurious takes of
delphinids from sonar and other active acoustic stressors or explosives
are requested or proposed for authorization. Further, the majority of
takes are anticipated to be by behavioral harassment in the form of
mild responses. Research and observations show that if delphinids are
exposed to sonar or other active acoustic sources they may react in a
number of ways depending on their experience with the sound source and
what activity they are engaged in at the time of the acoustic exposure.
Delphinids may not react at all until the sound source is approaching
within a few hundred meters to within a few kilometers depending on the
environmental conditions and species. Delphinids that are exposed to
activities that involve the use of sonar and other active acoustic
sources may alert, ignore the stimulus, change their behaviors or
vocalizations, avoid the sound source by swimming away or diving, or be
attracted to the sound source (Richardson, 1995; Nowacek, 2007;
Southall et al., 2007; Finneran and Jenkins, 2012). Research has
demonstrated that Alaska Resident killer whales may routinely move over
long large distances (Andrews and Matkin, 2014; Fearnbach et al.,
2013). In a similar documented long-distance movement, an Eastern North
Pacific Offshore stock killer whale tagged off San Clemente Island,
California, moved (over a period of 147 days) to waters off northern
Mexico, then north to Cook Inlet, Alaska, and finally (when the tag
ceased transmitting) to coastal waters off Southeast Alaska (Falcone
and Schorr, 2014). Given these findings, temporary displacement due to
avoidance of training activities are therefore unlikely to have
biological significance to individual animals.
Delphinid species generally travel in large pods and should be
visible from a distance in order to implement mitigation measures and
reduce potential impacts. Many of the recorded delphinid vocalizations
overlap with the MFAS/HFAS TTS frequency range (2-20 kHz); however, as
noted above, NMFS does not anticipate TTS of a serious degree or
extended duration to occur as a result of exposure to MFAS/HFAS.
Recovery from a threshold shift (TTS) can take a few minutes to a few
days, depending on the exposure duration, sound exposure level, and the
magnitude of the initial shift, with larger threshold shifts and longer
exposure durations requiring longer recovery times (Finneran et al.,
2005; Finneran and Schlundt, 2010; Mooney et al., 2009a; Mooney et al.,
2009b). However, large threshold shifts are not anticipated for these
activities because of the unlikelihood that animals will remain within
the ensonified area (due to the short duration of the majority of
exercises, the speed of the vessels, and the short distance within
which the animal would need to approach the sound source) at high
levels for the duration necessary to induce larger threshold shifts.
Threshold shifts do not necessarily affect all hearing frequencies
equally, so some threshold shifts may

[[Page 10010]]

not interfere with an animal's hearing of biologically relevant sounds.
Their size and detectability makes it unlikely that these animals would
be exposed to the higher energy or pressure expected to result in more
severe effects.
The predicted effects to delphinids are unlikely to cause long-term
consequences for individual animals or populations. The GOA TMAA
activities are not expected to occur in an area/time of specific
importance for reproductive, feeding, or other known critical behaviors
for delphinids. Stocks of delphinid species found in the Study Area are
not depleted under the MMPA, nor are they listed under the ESA.
Consequently, the activities are not expected to adversely impact rates
of recruitment or survival of delphinid species.
Porpoises--The Navy's acoustic analysis predicts that 16,244
instances of Level B harassment (TTS and behavioral) of Dall's porpoise
(Alaska stock) and 7,410 instances of Level B harassment of harbor
porpoise (GOA and Southeast Alaska stocks) may occur each year from
sonar and other active acoustic sources and explosives associated with
training and testing activities in the Study Area. These represent a
limited number of takes relative to population estimates for porpoise
stocks in the Study Area (Table 6). When the numbers of takes for
Dall's and harbor porpoise are compared to their respective estimated
stock abundances and if one assumes that each take happens to a
separate animal, less than 20 percent of the Alaska stock of Dall's
porpoise, and less than 18 percent of the GOA and Southeast Alaska
stocks of harbor porpoise would be harassed (behaviorally) during the
course of a year. Because the estimates given above represent the total
number of exposures and not necessarily the number of individuals
exposed, it is more likely that fewer individuals would be taken, but a
subset would be taken more than one time per year.
Behavioral responses can range from a mild orienting response, or a
shifting of attention, to flight and panic (Richardson, 1995; Nowacek,
2007; Southall et al., 2007). Acoustic analysis (factoring in the post-
model correction for avoidance and mitigation) also predicted that 5
Dall's porpoises might be exposed to sound levels from sonar and other
active acoustic stressors and explosives likely to result in PTS or
injury (Level A harassment).
The number of Dall's and harbor porpoise behaviorally harassed by
exposure to MFAS/HFAS in the Study Area is generally higher than the
other species. This is due to the low Level B harassment threshold (we
assume for the purpose of estimating take that all harbor porpoises
exposed to 120 dB or higher MFAS/HFAS will be taken by Level B
behavioral harassment), which essentially makes the ensonified area of
effects significantly larger than for the other species. However, the
fact that the threshold is a step function and not a curve (and
assuming uniform density) means that the vast majority of the takes
occur in the very lowest levels that exceed the threshold (it is
estimated that approximately 80 percent of the takes are from exposures
to 120 dB-126 dB), which means that anticipated behavioral effects are
not expected to be severe (e.g., temporary avoidance). As mentioned
above, an animal's exposure to a higher received level is more likely
to result in a behavioral response that is more likely to adversely
affect the health of an animal. Animals that do not exhibit a
significant behavioral reaction would likely recover from any incurred
costs, which reduces the likelihood of long-term consequences, such as
reduced fitness, for the individual or population.
Animals that experience hearing loss (TTS or PTS) may have reduced
ability to detect relevant sounds such as predators, prey, or social
vocalizations. Some porpoise vocalizations might overlap with the MFAS/
HFAS TTS frequency range (2-20 kHz). Recovery from a threshold shift
(TTS; partial hearing loss) can take a few minutes to a few days,
depending on the exposure duration, sound exposure level, and the
magnitude of the initial shift, with larger threshold shifts and longer
exposure durations requiring longer recovery times (Finneran et al.,
2005; Mooney et al., 2009a; Mooney et al., 2009b; Finneran and
Schlundt, 2010). More severe shifts may not fully recover and thus
would be considered PTS. However, large degrees of PTS are not
anticipated for these activities because of the unlikelihood that
animals will remain within the ensonified area (due to the short
duration of the majority of exercises, the speed of the vessels, and
the short distance within which the animal would need to approach the
sound source) at high levels for the duration necessary to induce
larger threshold shifts. Threshold shifts do not necessarily affect all
hearing frequencies equally, so some threshold shifts may not interfere
with an animal hearing biologically relevant sounds. The likely
consequences to the health of an individual that incurs PTS can range
from mild to more serious, depending upon the degree of PTS and the
frequency band it is in, and many animals are able to compensate for
the shift, although it may include energetic costs. Furthermore, likely
avoidance of intense activity and sound coupled with mitigation
measures would further reduce the potential for severe PTS exposures to
occur. If a marine mammal is able to approach a surface vessel within
the distance necessary to incur PTS, the likely speed of the vessel
(nominal 10-15 knots) would make it very difficult for the animal to
remain in range long enough to accumulate enough energy to result in
more than a mild case of PTS.
Harbor porpoises have been observed to be especially sensitive to
human activity (Tyack et al., 2011; Pirotta et al., 2012). The
information currently available regarding harbor porpoises suggests a
very low threshold level of response for both captive (Kastelein et
al., 2000; Kastelein et al., 2005) and wild (Johnston, 2002) animals.
Southall et al. (2007) concluded that harbor porpoises are likely
sensitive to a wide range of anthropogenic sounds at low received
levels (~ 90 to 120 dB). Research and observations of harbor porpoises
for other locations show that this small species is wary of human
activity and will display profound avoidance behavior for anthropogenic
sound sources in many situations at levels down to 120 dB re 1
[micro]Pa (Southall, 2007). Harbor porpoises routinely avoid and swim
away from large motorized vessels (Barlow et al., 1988; Evans et al.,
1994; Palka and Hammond, 2001; Polacheck and Thorpe, 1990). The
vaquita, which is closely related to the harbor porpoise in the Study
Area, appears to avoid large vessels at about 2,995 ft. (913 m)
(Jaramillo-Legorreta et al., 1999). The assumption is that the harbor
porpoise would respond similarly to large Navy vessels, possibly prior
to commencement of sonar or explosive activity (i.e., pre-activity
avoidance). Harbor porpoises may startle and temporarily leave the
immediate area of the training or testing until after the event ends.
ASW training exercises using MFAS/HFAS generally last for 2-16
hours, and may have intervals of non-activity in between. In addition,
the Navy does not typically conduct ASW exercises in the same
locations. Given the average length of ASW exercises (times of
continuous sonar use) and typical vessel speed, combined with the fact
that the majority of porpoises in the Study Area would not likely
remain in an area for successive days, it is unlikely that an animal
would be exposed to MFAS/HFAS at levels likely to result in a
substantive response (e.g., interruption

[[Page 10011]]

of feeding) that would then be carried on for more than one day or on
successive days. Thompson et al. (2013) showed that seismic surveys
conducted over a 10-day period in the North Sea did not result in the
broad-scale displacement of harbor porpoises away from preferred
habitat. The harbor porpoises were observed to leave the area at the
onset of survey, but returned within a few hours, and the overall
response of the porpoises decreased over the 10-day period.
Considering the information above, the predicted effects to Dall's
and harbor porpoise are unlikely to cause long-term consequences for
individual animals or the population. The GOA activities are not
expected to occur in an area/time of specific importance for
reproductive, feeding, or other known critical behaviors for Dall's and
harbor porpoise. Stocks of Dall's and harbor porpoise are not listed as
depleted under the MMPA. Consequently, the activities are not expected
to adversely impact annual rates of recruitment or survival of
porpoises.
Beaked Whales--Acoustic analysis predicts that 401 Baird's beaked
whales (Alaska stock), 2,544 Cuvier's beaked whales (Alaska stock), and
1,153 Stejneger's beaked whales (Alaska stock) will be taken annually
by Level B harassment from exposure to sonar and other active acoustic
stressors. These takes are anticipated to be in the form of behavioral
harassment (mainly behavioral reaction and some TTS) and no injurious
takes of beaked whales from sonar and other active acoustic stressors
or explosives are requested or proposed. Relative to population size,
training activities are anticipated to result only in a limited number
of takes. Because the estimates given above represent the total number
of exposures and not necessarily the number of individuals exposed, it
is more likely that fewer individuals would be taken, but a subset
would be taken more than one time per year. There are currently no
reliable abundance estimates for Alaska stocks of Baird's, Cuvier's,
and Stejner's beaked whales (Muto and Angliss, 2015).
As is the case with harbor porpoises, beaked whales have been shown
to be particularly sensitive to sound and therefore have been assigned
a lower harassment threshold based on observations of wild animals by
McCarthy et al. (2011) and Tyack et al. (2011). The fact that the Level
B harassment threshold is a step function (The Navy has adopted an
unweighted 140 dB re 1 [micro]Pa SPL threshold for significant
behavioral effects for all beaked whales) and not a curve (and assuming
uniform density) means that the vast majority of the takes occur in the
very lowest levels that exceed the threshold (it is estimated that
approximately 80 percent of the takes are from exposures to 140 dB to
146 dB), which means that the anticipated effects for the majority of
exposures are not expected to be severe (As mentioned above, an
animal's exposure to a higher received level is more likely to result
in a behavioral response that is more likely to adversely affect the
health of an animal). Further, Moretti et al. (2014) recently derived
an empirical risk function for Blainville's beaked whale that predicts
there is a 0.5 probability of disturbance at a received level of 150 dB
(CI: 144-155), suggesting that in some cases the current Navy step
function may over-estimate the effects of an activity using sonar on
beaked whales. Irrespective of the Moretti et al. (2014) risk function,
NMFS' analysis assumes that all of the beaked whale Level B takes that
are proposed for authorization will occur, and we base our negligible
impact determination, in part, on the fact that these exposures would
mainly occur at the very lowest end of the 140-dB behavioral harassment
threshold where behavioral effects are expected to be much less severe
and generally temporary in nature.
Behavioral responses can range from a mild orienting response, or a
shifting of attention, to flight and panic (Richardson, 1995; Nowacek,
2007; Southall et al., 2007; Finneran and Jenkins, 2012). Research has
also shown that beaked whales are especially sensitive to the presence
of human activity (Tyack et al., 2011; Pirotta et al., 2012). Beaked
whales have been documented to exhibit avoidance of human activity or
respond to vessel presence (Pirotta et al., 2012). Beaked whales were
observed to react negatively to survey vessels or low altitude aircraft
by quick diving and other avoidance maneuvers, and none were observed
to approach vessels (Wursig et al., 1998). Some beaked whale
vocalizations may overlap with the MFAS/HFAS TTS frequency range (2-20
kHz); however, as noted above, NMFS does not anticipate TTS of a
serious degree or extended duration to occur as a result of exposure to
MFA/HFAS. Recovery from a threshold shift (TTS) can take a few minutes
to a few days, depending on the exposure duration, sound exposure
level, and the magnitude of the initial shift, with larger threshold
shifts and longer exposure durations requiring longer recovery times
(Finneran et al., 2005; Mooney et al., 2009a; Mooney et al., 2009b;
Finneran and Schlundt, 2010). Large threshold shifts are not
anticipated for these activities because of the unlikelihood that
animals will remain within the ensonified area (due to the short
duration of the majority of exercises, the speed of the vessels, and
the short distance within which the animal would need to approach the
sound source) at high levels for the duration necessary to induce
larger threshold shifts. Threshold shifts do not necessarily affect all
hearing frequencies equally, so some threshold shifts may not interfere
with an animal's hearing of biologically relevant sounds.
It has been speculated for some time that beaked whales might have
unusual sensitivities to sonar sound due to their likelihood of
stranding in conjunction with MFAS use. Research and observations show
that if beaked whales are exposed to sonar or other active acoustic
sources they may startle, break off feeding dives, and avoid the area
of the sound source to levels of 157 dB re 1 [micro]Pa, or below
(McCarthy et al., 2011). Acoustic monitoring during actual sonar
exercises revealed some beaked whales continuing to forage at levels up
to 157 dB re 1 [micro]Pa (Tyack et al. 2011). Stimpert et al. (2014)
tagged a Baird's beaked whale, which was subsequently exposed to
simulated MFAS. Changes in the animal's dive behavior and locomotion
were observed when received level reached 127 dB re 1[mu]Pa. However,
Manzano-Roth et al. (2013) found that for beaked whale dives that
continued to occur during MFAS activity, differences from normal dive
profiles and click rates were not detected with estimated received
levels up to 137 dB re 1 [micro]Pa while the animals were at depth
during their dives. And in research done at the Navy's fixed tracking
range in the Bahamas, animals were observed to leave the immediate area
of the anti-submarine warfare training exercise (avoiding the sonar
acoustic footprint at a distance where the received level was ``around
140 dB'' SPL, according to Tyack et al. [2011]) but return within a few
days after the event ended (Claridge and Durban, 2009; Moretti et al.,
2009, 2010; Tyack et al., 2010, 2011; McCarthy et al., 2011). Tyack et
al. (2011) report that, in reaction to sonar playbacks, most beaked
whales stopped echolocating, made long slow ascent to the surface, and
moved away from the sound. A similar behavioral response study
conducted in Southern California waters during the 2010-2011 field
season found that Cuvier's beaked whales exposed to MFAS displayed
behavior ranging from initial orientation changes

[[Page 10012]]

to avoidance responses characterized by energetic fluking and swimming
away from the source (DeRuiter et al., 2013b). However, the authors did
not detect similar responses to incidental exposure to distant naval
sonar exercises at comparable received levels, indicating that context
of the exposures (e.g., source proximity, controlled source ramp-up)
may have been a significant factor. The study itself found the results
inconclusive and meriting further investigation. Cuvier's beaked whale
responses suggested particular sensitivity to sound exposure as
consistent with results for Blainville's beaked whale.
Populations of beaked whales and other odontocetes on the Bahamas
and other Navy fixed ranges that have been operating for decades,
appear to be stable. Behavioral reactions (avoidance of the area of
Navy activity) seem likely in most cases if beaked whales are exposed
to anti-submarine sonar within a few tens of kilometers, especially for
prolonged periods (a few hours or more) since this is one of the most
sensitive marine mammal groups to anthropogenic sound of any species or
group studied to date and research indicates beaked whales will leave
an area where anthropogenic sound is present (Tyack et al., 2011; De
Ruiter et al., 2013; Manzano-Roth et al., 2013; Moretti et al., 2014).
Research involving tagged Cuvier's beaked whales in the SOCAL Range
Complex reported on by Falcone and Schorr (2012, 2014) indicates year-
round prolonged use of the Navy's training and testing area by these
beaked whales and has documented movements in excess of hundreds of
kilometers by some of those animals. Given that some of these animals
may routinely move hundreds of kilometers as part of their normal
pattern, leaving an area where sonar or other anthropogenic sound is
present may have little, if any, cost to such an animal. Photo
identification studies in the SOCAL Range Complex, a Navy range that is
utilized for training and testing more frequently than the GOA TMAA
Study Area, have identified approximately 100 individual Cuvier's
beaked whale individuals with 40 percent having been seen in one or
more prior years, with re-sightings up to 7 years apart (Falcone and
Schorr, 2014). These results indicate long-term residency by
individuals in an intensively used Navy training and testing area,
which may also suggest a lack of long-term consequences as a result of
exposure to Navy training and testing activities. Finally, results from
passive acoustic monitoring estimated regional Cuvier's beaked whale
densities were higher than indicated by the NMFS's broad scale visual
surveys for the U.S. west coast (Hildebrand and McDonald, 2009).
Based on the findings above, it is clear that the Navy's long-term
ongoing use of sonar and other active acoustic sources has not
precluded beaked whales from also continuing to inhabit those areas. In
summary, based on the best available science, the Navy and NMFS believe
that beaked whales that exhibit a significant TTS or behavioral
reaction due to sonar and other active acoustic testing activities
would generally not have long-term consequences for individuals or
populations. Claridge (2013) speculated that sonar use in a Bahamas
range could have ``a possible population-level effect'' on beaked
whales based on lower abundance in comparison to control sites. In
summary, Claridge suggested that lower reproductive rates observed at
the Navy's Atlantic Undersea Test and Evaluation Center (AUTEC), when
compared to a control site, were due to stressors associated with
frequent and repeated use of Navy sonar. It is also important to note
that there were some relevant shortcomings of this study. For example,
all of the re-sighted whales during the 5-year study at both sites were
female, which Claridge acknowledged can lead to a negative bias in the
abundance estimation. There was also a reduced effort and shorter
overall study period at the AUTEC site that failed to capture some of
the emigration/immigration trends identified at the control site.
Furthermore, Claridge assumed that the two sites were identical and
therefore should have equal potential abundances; when in reality,
there were notable physical differences. The author also acknowledged
that ``information currently available cannot provide a quantitative
answer to whether frequent sonar use at [the Bahamas range] is causing
stress to resident beaked whales,'' and cautioned that the outcome of
ongoing studies ``is a critical component to understanding if there are
population-level effects.'' Moore and Barlow (2013) have noted a
decline in beaked whale populations in a broad area of the Pacific
Ocean area out to 300 nm from the coast and extending from the
Canadian-U.S. border to the tip of Baja Mexico. There are scientific
caveats and limitations to the data used for that analysis, as well as
oceanographic and species assemblage changes on the U.S. Pacific coast
not thoroughly addressed. Although Moore and Barlow (2013) have noted a
decline in the overall beaked whale population along the Pacific coast,
in the small fraction of that area where the Navy has been training and
testing with sonar and other systems for decades (the Navy's SOCAL
Range Complex), higher densities and long-term residency by individual
Cuvier's beaked whales suggest that the decline noted elsewhere is not
apparent where Navy sonar use is most intense. Navy sonar training and
testing is not conducted along a large part of the U.S. west coast from
which Moore and Barlow (2013) drew their survey data. In Southern
California, based on a series of surveys from 2006 to 2008 and a high
number encounter rate, Falcone et al. (2009) suggested the ocean basin
west of San Clemente Island may be an important region for Cuvier's
beaked whales given the number of animals encountered there. Follow-up
research (Falcone and Schorr, 2012, 2014) in this same location
suggests that Cuvier's beaked whales may have population sub-units with
higher than expected residency, particularly in the Navy's instrumented
Southern California Anti-Submarine Warfare Range. Encounters with
multiple groups of Cuvier's and Baird's beaked whales indicated not
only that they were prevalent on the range where Navy routinely trains
and tests, but also that they were potentially present in much higher
densities than had been reported for anywhere along the U.S. west coast
(Falcone et al., 2009, Falcone and Schorr, 2012). This finding is also
consistent with concurrent results from passive acoustic monitoring
that estimated regional Cuvier's beaked whale densities were higher
where Navy trains in the SOCAL training and testing area than indicated
by NMFS's broad scale visual surveys for the U.S. west coast
(Hildebrand and McDonald, 2009).
NMFS also considered New et al. (2013) and their mathematical model
simulating a functional link between foraging energetics and
requirements for survival and reproduction for 21 species of beaked
whales. However, NMFS concluded that New et al. (2013) model lacks
critical data and accurate inputs necessary to form valid conclusions
specifically about impacts of anthropogenic sound from Navy activities
on beaked whale populations. The study itself notes the need for
``future research,'' identifies ``key data needs'' relating to input
parameters that ``particularly affected'' the model results, and states
only that the use of the model ``in combination with more detailed
research'' could help predict the effects of management actions on
beaked whale species. In short,

[[Page 10013]]

information is not currently available to specifically support the use
of this model in a project-specific evaluation of the effects of Navy
activities on the impacted beaked whale species in GOA.
No beaked whales are predicted in the acoustic analysis to be
exposed to sound levels associated with PTS, other injury, or
mortality. After decades of the Navy conducting similar activities in
the GOA Study Area without incident, NMFS does not expect strandings,
injury, or mortality of beaked whales to occur as a result of training
activities. Stranding events coincident with Navy MFAS use in which
exposure to sonar is believed to have been a contributing factor were
detailed in the Stranding and Mortality section of this proposed rule.
However, for some of these stranding events, a causal relationship
between sonar exposure and the stranding could not be clearly
established (Cox et al., 2006). In other instances, sonar was
considered only one of several factors that, in their aggregate, may
have contributed to the stranding event (Freitas, 2004; Cox et al.,
2006). Because of the association between tactical MFAS use and a small
number of marine mammal strandings, the Navy and NMFS have been
considering and addressing the potential for strandings in association
with Navy activities for years. In addition to a suite of mitigation
measures intended to more broadly minimize impacts to marine mammals,
the reporting requirements set forth in this rule ensure that NMFS is
notified immediately (or as soon as clearance procedures allow) if a
stranded marine mammal is found during or shortly after, and in the
vicinity of, any Navy training exercise utilizing MFAS, HFAS, or
underwater explosive detonations (see General Notification of Injured
or Dead Marine Mammals and the Stranding Response Plan in the
regulatory text below). Additionally, through the MMPA process (which
allows for adaptive management), NMFS and the Navy will determine the
appropriate way to proceed in the event that a causal relationship were
to be found between Navy activities and a future stranding.
The GOA training activities are not expected to occur in an area/
time of specific importance for reproductive, feeding, or other known
critical behaviors for beaked whales. None of the Pacific stocks for
beaked whales species found in the Study Area are depleted under the
MMPA. The degree of predicted Level B harassment is expected to be
mild, and no beaked whales are predicted in the acoustic analysis to be
exposed to sound levels associated with PTS, other injury, or
mortality. Consequently, the activities are not expected to adversely
impact annual rates of recruitment or survival of beaked whales.
Pinnipeds--The Navy's acoustic analysis predicts that the following
numbers of Level B harassment (TTS and behavioral reaction) may occur
annually from sonar and other active acoustic stressors associated with
training activities: 1,243 Steller sea lions (Eastern U.S. and Western
U.S. stocks); 5 California sea lions (U.S. stock); 1,428 northern fur
seals (Eastern Pacific stock); 245 northern elephant seals (California
Breeding stock); and 4 harbor seals (North Kodiak, South Kodiak, and
Prince William Sound stocks). These represent a limited number of takes
relative to population estimates for pinniped stocks in the Study Area
(Table 6). When the numbers of behavioral takes are compared to the
estimated stock abundances, less than 2 percent of each of these stocks
would be behaviorally harassed during the course of a year. These
estimates represents the total number of exposures and not necessarily
the number of individuals exposed, as a single individual may be
exposed multiple times over the course of a year. Based on the
distribution information presented in the LOA application, it is highly
unlikely that ribbon seals would be encountered in the Study Area
during events involving use of sonar and other active acoustic sources
or explosives. The acoustic analysis did not predict any takes of
ribbon seals and NMFS is not authorizing any takes of this species.
Research has demonstrated that for pinnipeds, as for other mammals,
recovery from a threshold shift (TTS) can take a few minutes to a few
days, depending on the exposure duration, sound exposure level, and the
magnitude of the initial shift, with larger threshold shifts and longer
exposure durations requiring longer recovery times (Finneran et al.,
2005; Finneran and Schlundt, 2010; Mooney et al., 2009a; Mooney et al.,
2009b). However, large threshold shifts are not anticipated for these
activities because of the unlikelihood that animals will remain within
the ensonified area (due to the short duration of the majority of
exercises, the speed of the vessels, and the short distance within
which the animal would need to approach the sound source) at high
levels for the duration necessary to induce larger threshold shifts.
Threshold shifts do not necessarily affect all hearing frequencies
equally, so threshold shifts may not necessarily interfere with an
animal's ability to hear biologically relevant sounds.
Research and observations show that pinnipeds in the water may be
tolerant of anthropogenic noise and activity (a review of behavioral
reactions by pinnipeds to impulsive and non-impulsive noise can be
found in Richardson et al., 1995 and Southall et al., 2007). Available
data, though limited, suggest that exposures between approximately 90
and 140 dB SPL do not appear to induce strong behavioral responses in
pinnipeds exposed to nonpulse sounds in water (Jacobs and Terhune,
2002; Costa et al., 2003; Kastelein et al., 2006c). Based on the
limited data on pinnipeds in the water exposed to multiple pulses
(small explosives, impact pile driving, and seismic sources), exposures
in the approximately 150 to 180 dB SPL range generally have limited
potential to induce avoidance behavior in pinnipeds (Harris et al.,
2001; Blackwell et al., 2004; Miller et al., 2004). If pinnipeds are
exposed to sonar or other active acoustic sources they may react in a
number of ways depending on their experience with the sound source and
what activity they are engaged in at the time of the acoustic exposure.
Pinnipeds may not react at all until the sound source is approaching
within a few hundred meters and then may alert, ignore the stimulus,
change their behaviors, or avoid the immediate area by swimming away or
diving. Houser et al. (2013) performed a controlled exposure study
involving California sea lions exposed to a simulated MFAS signal. The
purpose of this Navy-sponsored study was to determine the probability
and magnitude of behavioral responses by California sea lions exposed
to differing intensities of simulated MFAS signals. Behavioral
reactions included increased respiration rates, prolonged submergence,
and refusal to participate, among others. Younger animals were more
likely to respond than older animals, while some sea lions did not
respond consistently at any level. Houser et al.'s findings are
consistent with current scientific studies and criteria development
concerning marine mammal reactions to MFAS. Effects on pinnipeds in the
Study Area that are taken by Level B harassment, on the basis of
reports in the literature as well as Navy monitoring from past
activities, will likely be limited to reactions such as increased
swimming speeds, increased surfacing time, or decreased foraging (if
such activity were occurring). Most likely, individuals will simply
move away from the sound source and be temporarily displaced from those
areas, or not respond at all. In areas of

[[Page 10014]]

repeated and frequent acoustic disturbance, some animals may habituate
or learn to tolerate the new baseline or fluctuations in noise level.
Habituation can occur when an animal's response to a stimulus wanes
with repeated exposure, usually in the absence of unpleasant associated
events (Wartzok et al., 2003). While some animals may not return to an
area, or may begin using an area differently due to training and
testing activities, most animals are expected to return to their usual
locations and behavior. Given their documented tolerance of
anthropogenic sound (Richardson et al., 1995 and Southall et al.,
2007), repeated exposures of individuals (e.g., harbor seals) to levels
of sound that may cause Level B harassment are unlikely to result in
hearing impairment or to significantly disrupt foraging behavior. As
stated above, pinnipeds may habituate to or become tolerant of repeated
exposures over time, learning to ignore a stimulus that in the past has
not accompanied any overt threat.
Thus, even repeated Level B harassment of some small subset of an
overall stock is unlikely to result in any significant realized
decrease in fitness to those individuals, and would not result in any
adverse impact to the stock as a whole. Evidence from areas where the
Navy extensively trains and tests provides some indication of the
possible consequences resulting from those proposed activities. In the
confined waters of Washington State's Hood Canal where the Navy has
been training and intensively testing for decades and harbor seals are
present year-round, the population level has remained stable suggesting
the area's carrying capacity likely has been reached (Jeffries et al.,
2003; Gaydos et al., 2013). Within Puget Sound there are several
locations where pinnipeds use Navy structures (e.g., submarines,
security barriers) for haulouts. Given that animals continue to choose
these areas for their resting behavior, it would appear there are no
long-term effects or consequences to those animals as a result of
ongoing and routine Navy activities.
Generally speaking, most pinniped stocks in the Study Area are
thought to be stable or increasing (Carretta et al., 2014, 2015).
Abundance estimates for pinniped stocks in the Study Area are shown in
Table 6. Relative to population size, training activities are
anticipated to result only in a limited number of takes. No areas of
specific importance for reproduction or feeding for pinnipeds have been
identified in the Study Area. Consequently, the activities are not
expected to adversely impact rates of recruitment or survival of
pinniped species.
Western U.S. stocks of Steller sea lions are listed as endangered
under the ESA; however, there is no designated critical habitat Steller
sea lions in the Study Area. As a conservative measure, the GOA TMAA
boundary zone was specifically drawn to exclude any nearby critical
habitat and associated terrestrial, air, or aquatic zones. NMFS is
currently engaged in an internal Section 7 consultation under the ESA
and the outcome of that consultation will further inform our final
determination.

Long-Term Consequences

The best assessment of long-term consequences from training
activities will be to monitor the populations over time within a given
Navy range complex. A U.S. workshop on Marine Mammals and Sound (Fitch
et al., 2011) indicated a critical need for baseline biological data on
marine mammal abundance, distribution, habitat, and behavior over
sufficient time and space to evaluate impacts from human-generated
activities on long-term population survival. The Navy has developed
monitoring plans for protected marine mammals occurring on Navy ranges
with the goal of assessing the impacts of training and testing
activities on marine species and the effectiveness of the Navy's
current mitigation practices. Continued monitoring efforts over time
will be necessary to completely evaluate the long-term consequences of
exposure to noise sources.
Since 2006 across all Navy range complexes (in the Atlantic, Gulf
of Mexico, and the Pacific), there have been more than 80 reports,
including Major Exercise Reports, Annual Exercise Reports, and
Monitoring Reports. For the Pacific since 2011, there have been 29
monitoring and exercise reports submitted to NMFS to further research
goals aimed at understanding the Navy's impact on the environment as it
carries out its mission to train and test.
In addition to this multi-year record of reports from across the
Navy, there have also been ongoing Behavioral Response Study research
efforts (in Southern California and the Bahamas) specifically focused
on determining the potential effects from Navy mid-frequency sonar
(Southall et al., 2011, 2012; McCarthy et al., 2011; Tyack et al.,
2011; DeRuiter et al., 2013b; Goldbogen et al., 2013; Moretti et al.,
2014). This multi-year compendium of monitoring, observation, study,
and broad scientific research is informative with regard to assessing
the effects of Navy training and testing in general. Given that this
record involves many of the same Navy training activities being
considered for the Study Area and because it includes all the marine
mammal taxonomic families and many of the same species, this compendium
of Navy reporting is directly applicable to assessing locations such as
the GOA TMAA.
In the Hawaii and Southern California Navy training and testing
ranges from 2009 to 2012, Navy-funded marine mammal monitoring research
completed over 5,000 hours of visual survey effort covering over 65,000
nautical miles, sighted over 256,000 individual marine mammals, took
over 45,600 digital photos and 36 hours of digital video, attached 70
satellite tracking tags to individual marine mammals, and collected
over 40,000 hours of passive acoustic recordings. In Hawaii alone
between 2006 and 2012, there were 21 scientific marine mammal surveys
conducted before, during, or after major exercises. This monitoring
effort is consistent with other research from these areas in that there
have been no direct evidence demonstration that routine Navy training
and testing has negatively impacted marine mammal populations
inhabiting these Navy ranges. Continued monitoring efforts over time
will be necessary to completely evaluate the long-term consequences of
exposure to noise sources. Other research findings related to the
general topic of long-term impacts are discussed above in the Species-
Specific Analysis.
Based on monitoring conducted before, during, and after Navy
training and testing events since 2006, the NMFS' assessment is that it
is unlikely there will be impacts having any long-term consequences to
populations of marine mammals as a result of the proposed continuation
of training and testing in the ocean areas historically used by the
Navy including the Study Area. This assessment of likelihood is based
on four indicators from areas in the Pacific where Navy training and
testing has been ongoing for decades: (1) Evidence suggesting or
documenting increases in the numbers of marine mammals present
(Calambokidis and Barlow, 2004; Falcone et al., 2009; Hildebrand and
McDonald, 2009; Falcone and Shorr, 2012; Calambokidis et al., 2009a;
Berman-Kowalewski et al., 2010; Moore and Barlow, 2011; Barlow et al.,
2011; Kerosky et al,. 2012; Smultea et al., 2013; [Scaron]irovi[cacute]
et al., 2015), (2) examples of documented presence and site fidelity of
species and long-term residence by individual animals of some species
(Hooker et al.,

[[Page 10015]]

2002; McSweeney et al., 2007; McSweeney et al., 2010; Martin and Kok,
2011; Baumann-Pickering et al., 2012; Falcone and Schorr, 2014), (3)
use of training and testing areas for breeding and nursing activities
(Littnan, 2010), and (4) 6 years of comprehensive monitoring data
indicating a lack of any observable effects to marine mammal
populations as a result of Navy training and testing activities.
To summarize, while the evidence covers most marine mammal
taxonomic suborders, it is limited to a few species and only suggestive
of the general viability of those species in intensively used Navy
training and testing areas (Barlow et al., 2011; Calambokidis et al.,
2009b; Falcone et al., 2009; Littnan, 2011; Martin and Kok, 2011;
McCarthy et al., 2011; McSweeney et al., 2007; McSweeney et al., 2009;
Moore and Barlow, 2011; Tyack et al., 2011; Southall et al., 2012a;
Melcon, 2012; Goldbogen, 2013; Baird et al., 2013). However, there is
no direct evidence that routine Navy training and testing spanning
decades has negatively impacted marine mammal populations at any Navy
Range Complex. Although there have been a few strandings associated
with use of sonar in other locations (see U.S. Department of the Navy,
2013b), Ketten (2012) has recently summarized, ``to date, there has
been no demonstrable evidence of acute, traumatic, disruptive, or
profound auditory damage in any marine mammal as the result of
anthropogenic noise exposures, including sonar.'' Therefore, based on
the best available science (Barlow et al., 2011; Carretta et al., 2011;
Falcone et al., 2009; Falcone and Schorr, 2012, 2014; Jeffries et al.,
2003; Littnan, 2011; Martin and Kok, 2011; McCarthy et al., 2011;
McSweeney et al., 2007; McSweeney et al., 2009; Moore and Barlow, 2011;
Tyack et al., 2011; Southall et al., 2012, 2013, 2014; Manzano-Roth et
al., 2013; DeRuiter et al., 2013b; Goldbogen et al., 2013; Moretti et
al., 2014; Smultea and Jefferson, 2014; [Scaron]irovi[cacute] et al.
2015), including data developed in the series of 80+ reports submitted
to NMFS, we believe that long-term consequences for individuals or
populations are unlikely to result from Navy training activities in the
Study Area.

Preliminary Determination

Training activities proposed in the GOA TMAA Study Area would
result in mainly Level B and some Level A takes, as summarized in
Tables 12 and 13. Based on best available science, NMFS concludes that
exposures to marine mammal species and stocks due to GOA TMAA
activities would result in individuals experiencing primarily short-
term (temporary and short in duration) and relatively infrequent
effects of the type or severity not expected to be additive. In
addition, only a generally small portion of the stocks and species is
likely to be exposed.
Marine mammal takes from Navy activities are not expected to impact
annual rates of recruitment or survival and will therefore not result
in population-level impacts for the following reasons:
Most acoustic exposures (greater than 99 percent) would be
within the non-injurious TTS or behavioral effects zones (Level B
harassment consisting of generally temporary modifications in behavior)
and none of the estimated exposures would result in mortality.
As mentioned earlier, an animal's exposure to a higher
received level is more likely to result in a behavioral response that
is more likely to adversely affect the health of the animal. For low
frequency cetaceans (mysticetes) in the Study Area, most Level B
exposures will occur at received levels less than 156 dB. The majority
of estimated odontocete takes from MFAS/HFAS (at least for hull-mounted
sonar, which is responsible for most of the sonar-related takes) also
result from exposures to received levels less than 156 dB. Therefore,
the majority of Level B takes are expected to be in the form of milder
responses (i.e., lower-level exposures that still rise to the level of
a take, but would likely be in the less severe range of responses that
qualify as a take), and are not expected to have deleterious impacts on
the fitness of any individuals. Marine mammal densities inputted into
the acoustic effects model are also conservative, particularly when
considering species for which data in portions of the Study Area is
limited, and when considering the seasonal migrations that extend
throughout the Study Area.
Acoustic disturbances caused by Navy sonar and explosives
are short-term, intermittent, and (in the case of sonar) transitory.
Even when an animal's exposure to active sonar may be more than one
time, the intermittent nature of the sonar signal, the signal's low
duty cycle (MFAS has a typical ping of every 50 seconds), and the fact
that both the vessel and animal are moving, provide a very small chance
that exposure to active sonar for individual animals and stocks would
be repeated over extended periods of time. Consequently, we would not
expect the Navy's activities to create conditions of long-term,
continuous underwater noise leading to habitat abandonment or long-term
hormonal or physiological stress responses in marine mammals.
Range complexes where intensive training and testing have
been occurring for decades have populations of multiple species with
strong site fidelity (including highly sensitive resident beaked whales
at some locations) and increases in the number of some species.
Populations of beaked whales and other odontocetes in the Bahamas, and
in other Navy fixed ranges that have been operating for tens of years,
appear to be stable.
Navy monitoring of Navy-wide activities since 2006 has
documented hundreds of thousands of marine mammals on the range
complexes and there are only two instances of overt behavioral change
that have been observed.
Navy monitoring of Navy-wide activities since 2006 has
documented no demonstrable instances of injury to marine mammals as a
result of non-impulsive acoustic sources.
In at least three decades of similar Navy activities, only
one instance of injury to marine mammals (March 25, 2011; three long-
beaked common dolphin off Southern California) has occurred as a known
result of training or testing using an impulsive source (underwater
explosion). Of note, the time-delay firing underwater explosive
training activity implicated in the March 4 incident is not proposed
for the training activities in the GOA Study Area.
The protective measures described in the Proposed
Mitigation section above are designed to reduce vessel strike potential
and avoid sound exposures that may cause serious injury, and to result
in the least practicable adverse effect on marine mammal species or
stocks.
Based on this analysis of the likely effects of the specified
activity on marine mammals and their habitat, which includes
consideration of the materials provided in the Navy's LOA application
and GOA DSEIS/OEIS, and dependent upon the implementation of the
mitigation and monitoring measures, NMFS finds that the total marine
mammal take from the Navy's training and testing activities in the GOA
Study Area will have a negligible impact on the affected marine mammal
species or stocks. NMFS proposes to issue regulations for these
activities in order to prescribe the means of effecting the least
practicable adverse impact on marine mammal species or stocks and their
habitat, and to set forth requirements pertaining to the monitoring and
reporting of that taking.

[[Page 10016]]

Subsistence Harvest of Marine Mammals

There are no relevant subsistence uses of marine mammals implicated
by this action. None of the proposed training activities in the Study
Area occur where traditional Arctic subsistence hunting exists.
Therefore, NMFS has preliminarily determined that the total taking
affecting species or stocks would not have an unmitigable adverse
impact on the availability of such species or stocks for taking for
subsistence purposes.

ESA

There are eight marine mammal species under NMFS jurisdiction that
are listed as endangered or threatened under the ESA with confirmed or
possible occurrence in the Study Area: Blue whale, fin whale, humpback
whale, sei whale, sperm whale, gray whale (Western North Pacific
stock), North Pacific right whale, and Steller sea lion (Western U.S.
stock). The Navy will consult with NMFS pursuant to section 7 of the
ESA, and NMFS will also consult internally on the issuance of a LOA
under section 101(a)(5)(A) of the MMPA for GOA TMAA activities.
Consultation will be concluded prior to a determination on the issuance
of the final rule and a LOA.

NEPA

NMFS is a cooperating agency on the Navy's GOA DSEIS/OEIS, which
was prepared and released to the public August 23, 2014. Upon
completion, the GOA Final SEIS/OEIS will be made available for public
review and posted on NMFS' Web site: http://www.nmfs.noaa.gov/pr/permits/incidental/military.htm. NMFS intends to adopt the GOA Final
SEIS/OEIS, if adequate and appropriate. Currently, we believe that the
adoption of the GOA Final SEIS/OEIS will allow NMFS to meet its
responsibilities under NEPA for the issuance of regulations and LOA for
GOA TMAA. If the GOA SEIS/OEIS is deemed inadequate by NMFS, NMFS would
supplement the existing analysis to ensure that we comply with NEPA
prior to issuing the final rule and LOA.

Classification

The Office of Management and Budget has determined that this
proposed rule is not significant for purposes of Executive Order 12866.
Pursuant to the Regulatory Flexibility Act (RFA), the Chief Counsel
for Regulation of the Department of Commerce has certified to the Chief
Counsel for Advocacy of the Small Business Administration that this
proposed rule, if adopted, would not have a significant economic impact
on a substantial number of small entities. The RFA requires federal
agencies to prepare an analysis of a rule's impact on small entities
whenever the agency is required to publish a notice of proposed
rulemaking. However, a federal agency may certify, pursuant to 5 U.S.C.
605 (b), that the action will not have a significant economic impact on
a substantial number of small entities. The Navy is the sole entity
that would be affected by this rulemaking, and the Navy is not a small
governmental jurisdiction, small organization, or small business, as
defined by the RFA. Any requirements imposed by an LOA issued pursuant
to these regulations, and any monitoring or reporting requirements
imposed by these regulations, would be applicable only to the Navy.
NMFS does not expect the issuance of these regulations or the
associated LOA to result in any impacts to small entities pursuant to
the RFA. Because this action, if adopted, would directly affect the
Navy and not a small entity, NMFS concludes the action would not result
in a significant economic impact on a substantial number of small
entities.

List of Subjects in 50 CFR Part 218

Exports, Fish, Imports, Incidental take, Indians, Labeling, Marine
mammals, Navy, Penalties, Reporting and recordkeeping requirements,
Seafood, Sonar, Transportation.

Dated: February 17, 2016.
Samuel D. Rauch III,
Deputy Assistant Administrator for Regulatory Programs, National Marine
Fisheries Service.

For reasons set forth in the preamble, 50 CFR part 218 is proposed
to be amended as follows:

PART 218--REGULATIONS GOVERNING THE TAKING AND IMPORTING OF MARINE
MAMMALS

0
1. The authority citation for part 218 continues to read as follows:

Authority: 16 U.S.C. 1361 et seq.

Subpart N--[Removed and Reserved]

0
3. Remove and reserve subpart N, consisting of Sec. Sec. 218.120
through 218.129.
0
4. Subpart P is added to part 218 to read as follows:
Subpart P--Taking and Importing Marine Mammals; U.S. Navy's Gulf of
Alaska Temporary Maritime Activities Area (GOA TMAA) Study Area
Sec.
218.150 Specified activity and specified geographical region.
218.151 Effective dates.
218.152 Permissible methods of taking.
218.153 Prohibitions.
218.154 Mitigation.
218.155 Requirements for monitoring and reporting.
218.156 Applications for letters of authorization.
218.157 Letters of authorization.
218.158 Renewal and modifications of letters of authorization and
adaptive management.

Subpart P--Taking and Importing Marine Mammals; U.S. Navy's Gulf of
Alaska Temporary Maritime Activities Area (GOA TMAA) Study Area

Sec. 218.150 Specified activity and specified geographical region.

(a) Regulations in this subpart apply only to the U.S. Navy for the
taking of marine mammals that occurs in the area outlined in paragraph
(b) of this section and that occurs incidental to the activities
described in paragraph (c) of this section.
(b) The taking of marine mammals by the Navy is only authorized if
it occurs within the GOA TMAA Study Area, which is bounded by a hexagon
with the following six corners: 57[deg]30'[deg] N. lat.,
141[deg]30'[deg] W. long.; 59[deg]36'[deg] N. lat., 148[deg]10'[deg] W.
long.; 58[deg]57'[deg] N. lat., 150[deg]04'[deg] W. long.;
58[deg]20'[deg] N. lat., 151[deg]00'[deg] W. long.; 57[deg]16'[deg] N.
lat., 151[deg]00'[deg] W. long.; and 55[deg]30'[deg] N. lat.,
142[deg]00'[deg] W. long.
(c) The taking of marine mammals by the Navy is only authorized if
it occurs incidental to the following activities:
(1) Sonar and other Active Sources Used During Training:
(i) Mid-frequency (MF) Source Classes:
(A) MF1--an average of 541 hours per year.
(B) MF3--an average of 48 hours per year.
(C) MF4--an average of 53 hours per year.
(D) MF5--an average of 25 items per year.
(E) MF6--an average of 21 items per year.
(F) MF11--an average of 78 hours per year.
(ii) High-frequency (HF) Source Classes:
(A) HF1--an average of 24 hours per year.
(B) HF6--an average of 80 items per year.
(iii) Anti-Submarine Warfare (ASW) Source Classes:
(A) ASW2--an average of 80 hours per year.
(B) ASW3--an average of 546 hours per year.
(C) ASW4--an average 4 items per year.

[[Page 10017]]

(iv) Torpedoes (TORP):
(A) TORP2--an average of 5 items per year.
(B) [Reserved]
(2) Impulsive Source Detonations During Training:
(i) Explosive Classes:
(A) E5 (>5 to 10 pound [lb] net explosive weight (NEW))--an average
of 112 detonations per year.
(B) E6 (>10 to 20 lb NEW)--an average of 2 detonations per year.
(C) E7 (>20 to 60 lb NEW)--an average of 4 detonations per year.
(D) E8 (>60 to 100 lb NEW)--an average of 6 detonations per year.
(E) E9 (>100 to 250 lb NEW)--an average of 142 detonations per
year.
(F) E10 (>250 to 500 lb NEW)--an average of 32 detonations per
year.
(G) E11 (>500 to 650 lb NEW)--an average of 2 detonations per year.
(H) E12 (>650 to 1,000 lb NEW)--an average of 4 detonations per
year.
(ii) [Reserved]

Sec. 218.151 Effective dates.

Regulations in this subpart are effective May 4, 2016, through May
3, 2021.

Sec. 218.152 Permissible methods of taking.

(a) Under letter of authorization (LOA) issued pursuant to
Sec. Sec. 216.106 and 218.157 of this chapter, the holder of the LOA
may incidentally, but not intentionally, take marine mammals within the
area described in Sec. 218.150, provided the activity is in compliance
with all terms, conditions, and requirements of these regulations and
the LOA.
(b) The activities identified in Sec. 218.150(c) must be conducted
in a manner that minimizes, to the greatest extent practicable, any
adverse impacts on marine mammals and their habitat.
(c) The incidental take of marine mammals under the activities
identified in Sec. 218.150(c) is limited to the following species, by
the identified method of take and the indicated number of times:
(1) Level B Harassment for all Training Activities:
(i) Mysticetes:
(A) Blue whale (Balaenoptera musculus), Eastern North Pacific--475
(an average of 95 per year).
(B) Fin whale (Balaenoptera physalus), Northeast Pacific--12,910
(an average of 2,582 per year).
(C) Humpback whale (Megaptera novaeangliae), Central North
Pacific--645 (an average of 129 per year).
(D) Humpback whale (Megaptera novaeangliae), Western North
Pacific--50 (an average of 10 per year).
(E) Minke whale (Balaenoptera acutorostrata), Alaska--435 (an
average of 87 per year).
(F) North Pacific right whale (Eubalaena japonica), Eastern North
Pacific--35 (an average of 7 per year).
(G) Sei whale (Balaenoptera borealis), Eastern North Pacific--65
(an average of 13 per year).
(ii) Odontocetes:
(A) Baird's beaked whale (Berardius bairdii), Alaska--2,005 (an
average of 401 per year).
(B) Cuvier's beaked whale (Ziphius cavirostris), Alaska--12,720 (an
average of 2,544 per year).
(C) Dall's porpoise (Phocoenoidea dalli), Alaska--81,220 (an
average of 16,244 per year).
(D) Harbor porpoise (Phocoena phocoena), GOA--27,420 (an average of
5,484 per year).
(E) Harbor porpoise (Phocoena phocoena), Southeast Alaska--9,630
(an average of 1,926 per year).
(F) Killer whale (Orcinus orca), Alaska Resident--2,820 (an average
of 564 per year).
(G) Killer whale (Orcinus orca), Eastern North Pacific Offshore--
265 (an average of 53 per year).
(H) Killer whale (Orcinus orca), AT1 Transient--5 (an average of 1
per year).
(I) Killer whale (Orcinus orca), GOA, Aleutian Island, and Bearing
Sea Transient--720 (an average of 144 per year).
(J) Pacific white-sided dolphin (Lagenorhynchus obliquidens), North
Pacific--9,815 (an average of 1,963 per year).
(K) Stejneger's beaked whale (Mesoplodon stejnegeri), Alaska--5,765
(an average of 1,153 per year).
(L) Sperm whale (Physeter macrocephalus), North Pacific--985 (an
average of 197 per year).
(iii) Pinnipeds:
(A) California sea lion (Zalophus californianus), U.S.--25 (an
average of 5 per year).
(B) Steller sea lion (Eumetopias jubatus), Eastern U.S.--3,355 (an
average of 671 per year).
(C) Steller sea lion (Eumetopias jubatus), Western U.S.--2,860 (an
average of 572 per year).
(D) Harbor seal (Phoca vitulina), North Kodiak--5 (an average of 1
per year).
(E) Harbor seal (Phoca vitulina), South Kodiak--5 (an average of 1
per year).
(F) Harbor seal (Phoca vitulina), Prince William Sound--10 (an
average of 2 per year).
(G) Northern elephant seal (Mirounga angustirostris), California
Breeding--1,225 (an average of 245 per year).
(H) Northern fur seal (Callorhinus ursinus), Eastern Pacific--7,140
(an average of 1,428 per year).
(2) Level A Harassment for all Training Activities:
(i) Odontocetes:
(A) Dall's porpoise (Phocoenoidea dalli), Alaska--25 (an average of
5 per year).
(B) [Reserved]
(ii) [Reserved]

Sec. 218.153 Prohibitions.

Notwithstanding takings contemplated in Sec. 218.152 and
authorized by an LOA issued under Sec. Sec. 216.106 and 218.157 of
this chapter, no person in connection with the activities described in
Sec. 218.150 may:
(a) Take any marine mammal not specified in Sec. 218.152(c);
(b) Take any marine mammal specified in Sec. 218.152(c) other than
by incidental take as specified in Sec. 218.152(c);
(c) Take a marine mammal specified in Sec. 218.152(c) if such
taking results in more than a negligible impact on the species or
stocks of such marine mammal; or
(d) Violate, or fail to comply with, the terms, conditions, and
requirements of these regulations or an LOA issued under Sec. Sec.
216.106 and 218.157 of this chapter.

Sec. 218.154 Mitigation.

(a) When conducting training activities, as identified in Sec.
218.150, the mitigation measures contained in the LOA issued under
Sec. Sec. 216.106 and 218.157 of this chapter must be implemented.
These mitigation measures include, but are not limited to:
(1) Lookouts.The Navy shall have two types of lookouts for the
purposes of conducting visual observations: Those positioned on ships;
and those positioned ashore, in aircraft, or on boats. The following
are protective measures concerning the use of lookouts.
(i) Lookouts positioned on surface ships shall be dedicated solely
to diligent observation of the air and surface of the water. Their
observation objectives shall include, but are not limited to, detecting
the presence of biological resources and recreational or fishing boats,
observing mitigation zones, and monitoring for vessel and personnel
safety concerns.
(ii) Due to manning and space restrictions on aircraft, small
boats, and some Navy ships, lookouts for these platforms may be
supplemented by the aircraft crew or pilot, boat crew, range site
personnel, or shore-side personnel. Lookouts positioned in minimally

[[Page 10018]]

manned platforms may be responsible for tasks in addition to observing
the air or surface of the water (e.g., navigation of a helicopter or
small boat). However, all lookouts shall, considering personnel safety,
practicality of implementation, and impact on the effectiveness of the
activity, comply with the observation objectives described above for
lookouts positioned on ships.
(iii) All personnel standing watch on the bridge, Commanding
Officers, Executive Officers, maritime patrol aircraft aircrews, anti-
submarine warfare helicopter crews, civilian equivalents, and lookouts
shall successfully complete the United States Navy Marine Species
Awareness Training prior to standing watch or serving as a lookout.
(iv) Lookout measures for non-impulsive sound:
(A) With the exception of vessels less than 65 ft (20 m) in length,
ships using hull-mounted mid-frequency active sonar sources associated
with anti-submarine warfare activities at sea shall have two Lookouts
at the forward position of the vessel.
(B) While using hull-mounted mid-frequency active sonar sources
associated with anti-submarine warfare activities at sea, vessels less
than 65 ft (20 m) in length shall have one lookout at the forward
position of the vessel due to space and manning restrictions.
(C) During non-hull mounted mid-frequency active sonar training
activities, Navy aircraft participating in exercises at sea shall
conduct and maintain, when operationally feasible and safe,
surveillance for marine species of concern as long as it does not
violate safety constraints or interfere with the accomplishment of
primary operational duties. Helicopters shall observe/survey the
vicinity of an anti-submarine warfare training event for 10 minutes
before the first deployment of active (dipping) sonar in the water.
(D) Ships or aircraft conducting non-hull-mounted mid-frequency
active sonar, such as helicopter dipping sonar systems, shall maintain
one lookout.
(E) Ships conducting high-frequency active sonar shall maintain one
lookout.
(v) Lookout measures for explosives and impulsive sound:
(A) Aircraft conducting explosive signal underwater sound buoy
activities using >0.5-2.5 lb. NEW shall have one lookout.
(B) Surface vessels or aircraft conducting small-, medium-, or
large-caliber gunnery exercises against a surface target shall have one
lookout. From the intended firing position, trained lookouts shall
survey the mitigation zone for marine mammals prior to commencement and
during the exercise as long as practicable. Towing vessels, if
applicable, shall also maintain one lookout. If a marine mammal is
sighted in the vicinity of the exercise, the tow vessel shall
immediately notify the firing vessel in order to secure gunnery firing
until the area is clear.
(C) Aircraft conducting explosive bombing exercises shall have one
lookout and any surface vessels involved shall have trained Lookouts.
If surface vessels are involved, lookouts shall survey for floating
kelp and marine mammals. Aircraft shall visually survey the target and
buffer zone for marine mammals prior to and during the exercise. The
survey of the impact area shall be made by flying at 1,500 ft. (460 m)
or lower, if safe to do so, and at the slowest safe speed. Release of
ordnance through cloud cover is prohibited: Aircraft must be able to
actually see ordnance impact areas. Survey aircraft should employ most
effective search tactics and capabilities.
(D) When aircraft are conducting missile exercises against a
surface target, the Navy shall have one Lookout positioned in an
aircraft. Aircraft shall visually survey the target area for marine
mammals. Visual inspection of the target area shall be made by flying
at 1,500 ft. (457 m) or lower, if safe to do so, and at slowest safe
speed. Firing or range clearance aircraft must be able to actually see
ordnance impact areas.
(E) Ships conducting explosive and non-explosive gunnery exercises
shall have one Lookout on the ship. This may be the same lookout
described in paragraph (B) above for surface vessels conducting small-,
medium-, or large-caliber gunnery exercises when that activity is
conducted from a ship against a surface target.
(F) During sinking exercises, two Lookouts shall be used. One
lookout shall be positioned in an aircraft and one lookout shall be
positioned on a vessel.
(vi) Lookout measures for physical strike and disturbance:
(A) While underway, surface ships shall have at least one lookout.
(B) [Reserved]
(vii) Lookout measures for non-explosive practice munitions:
(A) Gunnery exercises using non-explosive practice munitions (e.g.,
small-, medium-, and large-caliber) using a surface target shall have
one lookout.
(B) During non-explosive bombing exercises one lookout shall be
positioned in an aircraft and trained lookouts shall be positioned in
any surface vessels involved.
(C) When aircraft are conducting non-explosive missile exercises
(including exercises using rockets) against a surface target, the Navy
shall have one lookout positioned in an aircraft.
(2) Mitigation Zones--The following are protective measures
concerning the implementation of mitigation zones.
(i) Mitigation zones shall be measured as the radius from a source
and represent a distance to be monitored.
(ii) Visual detections of marine mammals or sea turtles within a
mitigation zone shall be communicated immediately to a watch station
for information dissemination and appropriate action.
(iii) Mitigation zones for non-impulsive sound:
(A) The Navy shall ensure that hull-mounted mid-frequency active
sonar transmission levels are limited to at least 6 dB below normal
operating levels if any detected marine mammals or sea turtles are
within 1,000 yd. (914 m) of the sonar dome (the bow).
(B) The Navy shall ensure that hull-mounted mid-frequency active
sonar transmissions are limited to at least 10 dB below the equipment's
normal operating level if any detected marine mammals or sea turtles
are within 500 yd. (457 m) of the sonar dome.
(C) The Navy shall ensure that hull-mounted mid-frequency active
sonar transmissions are ceased if any detected cetaceans or sea turtles
are within 200 yd. (183 m) and pinnipeds are within 100 yd. (90 m) of
the sonar dome. Transmissions shall not resume until the marine mammal
has been observed exiting the mitigation zone, is thought to have
exited the mitigation zone based on its course and speed, has not been
detected for 30 minutes, the vessel has transited more than 2,000 yd.
beyond the location of the last detection, or the ship concludes that
dolphins are deliberately closing in on the ship to ride the ship's bow
wave (and there are no other marine mammal sightings within the
mitigation zone). Active transmission may resume when dolphins are bow
riding because they are out of the main transmission axis of the active
sonar while in the shallow-wave area of the ship bow.
(D) The Navy shall ensure that high-frequency and non-hull-mounted
mid-frequency active sonar transmission levels are ceased if any
detected cetaceans are within 200 yd. (180 m) and pinnipeds are within
100 yd. (90 m) of the source. Transmissions shall not resume until the
marine mammal has been observed exiting the mitigation zone, is thought
to have exited the mitigation zone based on its course and speed, the
mitigation zone has been

[[Page 10019]]

clear from any additional sightings for a period of 10 minutes for an
aircraft-deployed source, the mitigation zone has been clear from any
additional sightings for a period of 30 minutes for a vessel-deployed
source, the vessel or aircraft has repositioned itself more than 400
yd. (370 m) away from the location of the last sighting, or the vessel
concludes that dolphins are deliberately closing in to ride the
vessel's bow wave (and there are no other marine mammal sightings
within the mitigation zone).
(iv) Mitigation zones for explosive and impulsive sound:
(A) A mitigation zone with a radius of 350 yd. (320 m) shall be
established for explosive signal underwater sonobuoys using >0.5 to 2.5
lb NEW. Explosive signal underwater sonobuoys shall not be deployed if
concentrations of floating vegetation (kelp paddies) are observed in
the mitigation zone (around the intended deployment location).
Explosive signal underwater sonobuoy deployment shall cease if a marine
mammal is sighted within the mitigation zone. Detonations shall
recommence if any one of the following conditions is met: The animal is
observed exiting the mitigation zone, the animal is thought to have
exited the mitigation zone based on its course and speed, or the
mitigation zone has been clear from any additional sightings for a
period of 10 minutes. Passive acoustic monitoring shall also be
conducted with Navy assets, such as sonobuoys, already participating in
the activity. These assets would only detect vocalizing marine mammals
within the frequency bands monitored by Navy personnel. Passive
acoustic detections would not provide range or bearing to detected
animals, and therefore cannot provide locations of these animals.
Passive acoustic detections would be reported to Lookouts posted in
aircraft in order to increase vigilance of their visual surveillance.
(B) A mitigation zone with a radius of 200 yd. (180 m) shall be
established for small- and medium-caliber gunnery exercises with a
surface target. The exercise shall not commence if concentrations of
floating vegetation (kelp paddies) are observed in the mitigation zone.
Firing shall cease if a marine mammal is sighted within the mitigation
zone. Firing shall recommence if any one of the following conditions is
met: The animal is observed exiting the mitigation zone, the animal is
thought to have exited the mitigation zone based on its course and
speed, the mitigation zone has been clear from any additional sightings
for a period of 10 minutes for a firing aircraft, the mitigation zone
has been clear from any additional sightings for a period of 30 minutes
for a firing ship, or the intended target location has been
repositioned more than 400 yd. (370 m) away from the location of the
last sighting.
(C) A mitigation zone with a radius of 600 yd. (549 m) shall be
established for large-caliber gunnery exercises with a surface target.
The exercise shall not commence if concentrations of floating
vegetation (kelp paddies) are observed in the mitigation zone. Firing
shall cease if a marine mammal is sighted within the mitigation zone.
Firing shall recommence if any one of the following conditions is met:
The animal is observed exiting the mitigation zone, the animal is
thought to have exited the mitigation zone based on its course and
speed, or the mitigation zone has been clear from any additional
sightings for a period of 30 minutes.
(D) A mitigation zone with a radius of 900 yd. (823 m) shall be
established for missile exercises with up to 250 lb NEW and a surface
target. The exercise shall not commence if concentrations of floating
vegetation (kelp paddies) are observed in the mitigation zone. Firing
shall cease if a marine mammal is sighted within the mitigation zone.
Firing shall recommence if any one of the following conditions is met:
The animal is observed exiting the mitigation zone, the animal is
thought to have exited the mitigation zone based on its course and
speed, or the mitigation zone has been clear from any additional
sightings for a period of 10 minutes or 30 minutes (depending on
aircraft type).
(E) A mitigation zone with a radius of 2,000 yd. (1.8 km) shall be
established for missile exercises with 251 to 500 lb NEW using a
surface target. The exercise shall not commence if concentrations of
floating vegetation (kelp paddies) are observed in the mitigation zone.
Firing shall cease if a marine mammal is sighted within the mitigation
zone. Firing shall recommence if any one of the following conditions is
met: The animal is observed exiting the mitigation zone, the animal is
thought to have exited the mitigation zone based on its course and
speed, or the mitigation zone has been clear from any additional
sightings for a period of 10 minutes or 30 minutes (depending on
aircraft type).
(F) A mitigation zone with a radius of 2,500 yd. (2.3 km) around
the intended impact location for explosive bombs and 1000 yd. (920 m)
for non-explosive bombs shall be established for bombing exercises. The
exercise shall not commence if concentrations of floating vegetation
(kelp paddies) are observed in the mitigation zone. Bombing shall cease
if a marine mammal is sighted within the mitigation zone. Bombing shall
recommence if any one of the following conditions is met: The animal is
observed exiting the mitigation zone, the animal is thought to have
exited the mitigation zone based on its course and speed, or the
mitigation zone has been clear from any additional sightings for a
period of 10 minutes.
(G) A mitigation zone with a radius of 2.5 nautical miles shall be
established for sinking exercises. Sinking exercises shall include
aerial observation beginning 90 minutes before the first firing, visual
observations from vessels throughout the duration of the exercise, and
both aerial and vessel observation immediately after any planned or
unplanned breaks in weapons firing of longer than 2 hours. Prior to
conducting the exercise, the Navy shall review remotely sensed sea
surface temperature and sea surface height maps to aid in deciding
where to release the target ship hulk. The Navy shall also monitor
using passive acoustics during the exercise. Passive acoustic
monitoring would be conducted with Navy assets, such as passive ships
sonar systems or sonobuoys, already participating in the activity.
These assets would only detect vocalizing marine mammals within the
frequency bands monitored by Navy personnel. Passive acoustic
detections would not provide range or bearing to detected animals, and
therefore cannot provide locations of these animals. Passive acoustic
detections would be reported to lookouts posted in aircraft and on
vessels in order to increase vigilance of their visual surveillance.
Lookouts shall also increase observation vigilance before the use of
torpedoes or unguided ordnance with a NEW of 500 lb. or greater, or if
the Beaufort sea state is a 4 or above. The exercise shall not commence
if concentrations of floating vegetation (kelp paddies) are observed in
the mitigation zone. The exercise shall cease if a marine mammal, sea
turtle, or aggregation of jellyfish is sighted within the mitigation
zone. The exercise shall recommence if any one of the following
conditions is met: The animal is observed exiting the mitigation zone,
the animal is thought to have exited the mitigation zone based on a
determination of its course and speed and the relative motion between
the animal and the source, or the mitigation zone has been clear from
any additional sightings for a period of 30 minutes. Upon sinking the
vessel, the Navy shall conduct post-exercise visual surveillance of the
mitigation zone for 2

[[Page 10020]]

hours (or until sunset, whichever comes first).
(H) A mitigation zone of 70 yd. (46 m) shall be established for all
explosive large-caliber gunnery exercises conducted from a ship. The
exercise shall not commence if concentrations of floating vegetation
(kelp paddies) are observed in the mitigation zone. Firing shall cease
if a marine mammal is sighted within the mitigation zone. Firing shall
recommence if any one of the following conditions is met: The animal is
observed exiting the mitigation zone, the animal is thought to have
exited the mitigation zone based on its course and speed, the
mitigation zone has been clear from any additional sightings for a
period of 30 minutes, or the vessel has repositioned itself more than
140 yd. (128 m) away from the location of the last sighting.
(v) Mitigation zones for vessels and in-water devices:
(A) A mitigation zone of 500 yd. (460 m) for observed whales and
200 yd (183 m) for all other marine mammals (except bow riding
dolphins) shall be established for all vessel movement during training
activities, providing it is safe to do so.
(B) A mitigation zone of 250 yd. (229 m) shall be established for
all towed in-water devices, providing it is safe to do so.
(vi) Mitigation zones for non-explosive practice munitions:
(A) A mitigation zone of 200 yd. (180 m) shall be established for
small, medium, and large caliber gunnery exercises using a surface
target. The exercise shall not commence if concentrations of floating
vegetation (kelp paddies) are observed in the mitigation zone. Firing
shall cease if a marine mammal is sighted within the mitigation zone.
Firing shall recommence if any one of the following conditions is met:
The animal is observed exiting the mitigation zone, the animal is
thought to have exited the mitigation zone based on its course and
speed, the mitigation zone has been clear from any additional sightings
for a period of 10 minutes for a firing aircraft, the mitigation zone
has been clear from any additional sightings for a period of 30 minutes
for a firing ship, or the intended target location has been
repositioned more than 400 yd. (370 m) away from the location of the
last sighting.
(B) A mitigation zone of 1,000 yd. (920 m) shall be established for
bombing exercises. Bombing shall cease if a marine mammal is sighted
within the mitigation zone. The exercise shall not commence if
concentrations of floating vegetation (kelp paddies) are observed in
the mitigation zone. Bombing shall recommence if any one of the
following conditions is met: The animal is observed exiting the
mitigation zone, the animal is thought to have exited the mitigation
zone based on its course and speed, or the mitigation zone has been
clear from any additional sightings for a period of 10 minutes.
(C) A mitigation zone of 900 yd. (823 m) shall be established for
missile exercises (including rockets) using a surface target. The
exercise shall not commence if concentrations of floating vegetation
(kelp paddies) are observed in the mitigation zone. Firing shall cease
if a marine mammal is sighted within the mitigation zone. Firing shall
recommence if any one of the following conditions is met: The animal is
observed exiting the mitigation zone, the animal is thought to have
exited the mitigation zone based on its course and speed, or the
mitigation zone has been clear from any additional sightings for a
period of 10 minutes or 30 minutes (depending on aircraft type).
(3) Stranding response plan. (i) The Navy shall abide by the letter
of the ``Stranding Response Plan for Major Navy Training Exercises in
the GOA TMAA Study Area,'' to include the following measures:
(A) Shutdown procedures. When an Uncommon Stranding Event (USE)
occurs during a Major Training Exercise (MTE) in the Study Area, the
Navy shall implement the procedures described below:
(1) The Navy shall implement a shutdown when advised by a NMFS
Office of Protected Resources Headquarters Senior Official designated
in the GOA TMAA Study Area Stranding Communication Protocol that a USE
involving live animals has been identified and that at least one live
animal is located in the water. NMFS and the Navy shall maintain a
dialogue, as needed, regarding the identification of the USE and the
potential need to implement shutdown procedures.
(2) Any shutdown in a given area shall remain in effect in that
area until NMFS advises the Navy that the subject(s) of the USE at that
area die or are euthanized, or that all live animals involved in the
USE at that area have left the area (either of their own volition or
herded).
(3) If the Navy finds an injured or dead animal floating at sea
during an MTE, the Navy shall notify NMFS immediately or as soon as
operational security considerations allow. The Navy shall provide NMFS
with species or description of the animal(s), the condition of the
animal(s), including carcass condition if the animal(s) is/are dead,
location, time of first discovery, observed behavior (if alive), and
photo or video (if available). Based on the information provided, NFMS
shall determine if, and advise the Navy whether a modified shutdown is
appropriate on a case-by-case basis.
(4) In the event, following a USE, that qualified individuals are
attempting to herd animals back out to the open ocean and animals are
not willing to leave, or animals are seen repeatedly heading for the
open ocean but turning back to shore, NMFS and the Navy shall
coordinate (including an investigation of other potential anthropogenic
stressors in the area) to determine if the proximity of mid-frequency
active sonar training activities or explosive detonations, though
farther than 14 nautical miles from the distressed animal(s), is likely
contributing to the animals' refusal to return to the open water. If
so, NMFS and the Navy shall further coordinate to determine what
measures are necessary to improve the probability that the animals will
return to open water and implement those measures as appropriate.
(B) Within 72 hours of NMFS notifying the Navy of the presence of a
USE, the Navy shall provide available information to NMFS (per the GOA
TMAA Study Area Communication Protocol) regarding the location, number
and types of acoustic/explosive sources, direction and speed of units
using mid-frequency active sonar, and marine mammal sightings
information associated with training activities occurring within 80
nautical miles (148 km) and 72 hours prior to the USE event.
Information not initially available regarding the 80-nautical miles
(148-km), 72-hour period prior to the event shall be provided as soon
as it becomes available. The Navy shall provide NMFS investigative
teams with additional relevant unclassified information as requested,
if available.
(ii) [Reserved]
(b) [Reserved]

Sec. 218.155 Requirements for monitoring and reporting.

(a) The Holder of the Authorization must notify NMFS immediately
(or as soon as operational security considerations allow) if the
specified activity identified in Sec. 218.150 is thought to have
resulted in the mortality or injury of any marine mammals, or in any
take of marine mammals not identified in Sec. 218.152(c).
(b) The Holder of the LOA must conduct all monitoring and required
reporting under the LOA, including abiding by the GOA TMAA monitoring
plan.

[[Page 10021]]

(c) General notification of injured or dead marine mammals. Navy
personnel shall ensure that NMFS (regional stranding coordinator) is
notified immediately (or as soon as operational security considerations
allow) if an injured or dead marine mammal is found during or shortly
after, and in the vicinity of, a Navy training activity utilizing mid-
or high-frequency active sonar, or underwater explosive detonations.
The Navy shall provide NMFS with species or description of the
animal(s), the condition of the animal(s) (including carcass condition
if the animal is dead), location, time of first discovery, observed
behaviors (if alive), and photo or video (if available). In the event
that an injured, stranded, or dead marine mammal is found by the Navy
that is not in the vicinity of, or during or shortly after, MFAS, HFAS,
or underwater explosive detonations, the Navy shall report the same
information as listed above as soon as operationally feasible and
clearance procedures allow.
(d) General notification of ship strike. In the event of a ship
strike by any Navy vessel, at any time or place, the Navy shall do the
following:
(1) Immediately report to NMFS the species identification (if
known), location (lat/long) of the animal (or the strike if the animal
has disappeared), and whether the animal is alive or dead (or unknown),
and the time of the strike.
(2) Report to NMFS as soon as operationally feasible the size and
length of animal, an estimate of the injury status (ex., dead, injured
but alive, injured and moving, unknown, etc.), vessel class/type and
operational status.
(3) Report to NMFS the vessel length, speed, and heading as soon as
feasible.
(4) Provide NMFS a photo or video, if equipment is available.
(5) Within 2 weeks of the strike, provide NMFS with a detailed
description of the specific actions of the vessel in the 30-minute
timeframe immediately preceding the strike, during the event, and
immediately after the strike (e.g., the speed and changes in speed, the
direction and changes in direction, other maneuvers, sonar use, etc.,
if not classified); a narrative description of marine mammal sightings
during the event and immediately after, and any information as to
sightings prior to the strike, if available; and use established Navy
shipboard procedures to make a camera available to attempt to capture
photographs following a ship strike.
(e) Communication plan. The Navy and NMFS shall develop a
communication plan that will include all of the communication protocols
(phone trees, etc.) and associated contact information required for
NMFS and the Navy to carry out the necessary expeditious communication
required in the event of a stranding or ship strike, including
information described in the proposed notification measures above.
(f) Annual GOA TMAA monitoring report. The Navy shall submit an
annual report of the GOA TMAA monitoring describing the implementation
and results from the previous calendar year. Data collection methods
shall be standardized across range complexes and study areas to allow
for comparison in different geographic locations. Although additional
information will be gathered, the protected species observers
collecting marine mammal data pursuant to the GOA TMAA monitoring plan
shall, at a minimum, provide the same marine mammal observation data
required in Sec. 218.155. The report shall be submitted either 90 days
after the calendar year, or 90 days after the conclusion of the
monitoring year to be determined by the Adaptive Management process.
The GOA TMAA Monitoring Report may be provided to NMFS within a larger
report that includes the required Monitoring Plan reports from multiple
range complexes and study areas (the multi-Range Complex Annual
Monitoring Report). Such a report would describe progress of knowledge
made with respect to monitoring plan study questions across all Navy
ranges associated with the Integrated Comprehensive Monitoring Program.
Similar study questions shall be treated together so that progress on
each topic shall be summarized across all Navy ranges. The report need
not include analyses and content that does not provide direct
assessment of cumulative progress on the monitoring plan study
questions.
(g) Annual GOA TMAA exercise reports. Each year, the Navy shall
submit a preliminary report detailing the status of authorized sound
sources within 21 days after the anniversary of the date of issuance of
the LOA. Each year, the Navy shall submit a detailed report within 3
months after the anniversary of the date of issuance of the LOA. The
annual report shall contain information on Major Training Exercises
(MTEs), Sinking Exercise (SINKEX) events, and a summary of all sound
sources used, as described in paragraph (g)(3) of this section. The
analysis in the detailed report shall be based on the accumulation of
data from the current year's report and data collected from previous
the report. The detailed reports shall contain information identified
in paragraphs (g)(1) through (4) of this section.
(1) MFAS/HFAS Major Training Exercises--This section shall contain
the following information for Major Training Exercises conducted in the
GOA TMAA:
(i) Exercise Information (for each MTE):
(A) Exercise designator.
(B) Date that exercise began and ended.
(C) Location.
(D) Number and types of active sources used in the exercise.
(E) Number and types of passive acoustic sources used in exercise.
(F) Number and types of vessels, aircraft, etc., participating in
exercise.
(G) Total hours of observation by lookouts.
(H) Total hours of all active sonar source operation.
(I) Total hours of each active sonar source bin.
(J) Wave height (high, low, and average during exercise).
(ii) Individual marine mammal sighting information for each
sighting in each exercise when mitigation occurred:
(A) Date/Time/Location of sighting.
(B) Species (if not possible, indication of whale/dolphin/
pinniped).
(C) Number of individuals.
(D) Initial Detection Sensor.
(E) Indication of specific type of platform observation made from
(including, for example, what type of surface vessel or testing
platform).
(F) Length of time observers maintained visual contact with marine
mammal.
(G) Sea state.
(H) Visibility.
(I) Sound source in use at the time of sighting.
(J) Indication of whether animal is <200 yd, 200 to 500 yd, 500 to
1,000 yd, 1,000 to 2,000 yd, or >2,000 yd from sonar source.
(K) Mitigation implementation. Whether operation of sonar sensor
was delayed, or sonar was powered or shut down, and how long the delay
was.
(L) If source in use is hull-mounted, true bearing of animal from
ship, true direction of ship's travel, and estimation of animal's
motion relative to ship (opening, closing, parallel).
(M) Observed behavior. Lookouts shall report, in plain language and
without trying to categorize in any way, the observed behavior of the
animals (such as animal closing to bow ride, paralleling course/speed,
floating on surface and not swimming, etc.) and if any calves present.
(iii) An evaluation (based on data gathered during all of the MTEs)
of the effectiveness of mitigation measures designed to minimize the
received level

[[Page 10022]]

to which marine mammals may be exposed. This evaluation shall identify
the specific observations that support any conclusions the Navy reaches
about the effectiveness of the mitigation.
(2) SINKEXs. This section shall include the following information
for each SINKEX completed that year:
(i) Exercise information (gathered for each SINKEX):
(A) Location.
(B) Date and time exercise began and ended.
(C) Total hours of observation by lookouts before, during, and
after exercise.
(D) Total number and types of explosive source bins detonated.
(E) Number and types of passive acoustic sources used in exercise.
(F) Total hours of passive acoustic search time.
(G) Number and types of vessels, aircraft, etc., participating in
exercise.
(H) Wave height in feet (high, low, and average during exercise).
(I) Narrative description of sensors and platforms utilized for
marine mammal detection and timeline illustrating how marine mammal
detection was conducted.
(ii) Individual marine mammal observation (by Navy lookouts)
information (gathered for each marine mammal sighting) for each
sighting in each exercise that required mitigation to be implemented:
(A) Date/Time/Location of sighting.
(B) Species (if not possible, indicate whale, dolphin, or
pinniped).
(C) Number of individuals.
(D) Initial detection sensor.
(E) Length of time observers maintained visual contact with marine
mammal.
(F) Sea state.
(G) Visibility.
(H) Whether sighting was before, during, or after detonations/
exercise, and how many minutes before or after.
(I) Distance of marine mammal from actual detonations (or target
spot if not yet detonated).
(J) Observed behavior. Lookouts shall report, in plain language and
without trying to categorize in any way, the observed behavior of the
animal(s) (such as animal closing to bow ride, paralleling course/
speed, floating on surface and not swimming etc.), including speed and
direction and if any calves present.
(K) Resulting mitigation implementation. Indicate whether explosive
detonations were delayed, ceased, modified, or not modified due to
marine mammal presence and for how long.
(L) If observation occurs while explosives are detonating in the
water, indicate munition type in use at time of marine mammal
detection.
(3) Summary of sources used.
(i) This section shall include the following information summarized
from the authorized sound sources used in all training events:
(A) Total annual hours or quantity (per the LOA) of each bin of
sonar or other non-impulsive source;
(B) Total annual number of each type of explosive exercises (of
those identified as part of the ``Specified Activity'' in this proposed
rule) and total annual expended/detonated rounds (missiles, bombs,
sonobuoys, etc.) for each explosive bin.
(4) Geographic information presentation. The reports shall present
an annual (and seasonal, where practical) depiction of training
exercises and testing bin usage geographically across the Study Area.
(g) Sonar exercise notification. The Navy shall submit to NMFS
(contact as specified in the LOA) an electronic report within fifteen
calendar days after the completion of any major training exercise
indicating:
(i) Location of the exercise.
(ii) Beginning and end dates of the exercise.
(iii) Type of exercise.
(h) Five-year close-out exercise report. This report shall be
included as part of the 2021 annual exercise report. This report shall
provide the annual totals for each sound source bin with a comparison
to the annual allowance and the 5-year total for each sound source bin
with a comparison to the 5-year allowance. Additionally, if there were
any changes to the sound source allowance, this report shall include a
discussion of why the change was made and include the analysis to
support how the change did or did not result in a change in the SEIS
and final rule determinations. The report shall be submitted 3 months
after the expiration of this subpart. NMFS shall submit comments on the
draft close-out report, if any, within 3 months of receipt. The report
shall be considered final after the Navy has addressed NMFS' comments,
or 3 months after the submittal of the draft if NMFS does not provide
comments.

Sec. 218.156 Applications for letters of authorization (LOA).

To incidentally take marine mammals pursuant to the regulations in
this subpart, the U.S. citizen (as defined by Sec. 216.106 of this
chapter) conducting the activity identified in Sec. 218.150(c) (the
U.S. Navy) must apply for and obtain either an initial LOA in
accordance with Sec. 218.157 or a renewal under Sec. 218.158.

Sec. 218.157 Letters of authorization (LOA).

(a) An LOA, unless suspended or revoked, shall be valid for a
period of time not to exceed the period of validity of this subpart.
(b) Each LOA shall set forth:
(1) Permissible methods of incidental taking;
(2) Means of effecting the least practicable adverse impact on the
species, its habitat, and on the availability of the species for
subsistence uses (i.e., mitigation); and
(3) Requirements for mitigation, monitoring and reporting.
(c) Issuance and renewal of the LOA shall be based on a
determination that the total number of marine mammals taken by the
activity as a whole shall have no more than a negligible impact on the
affected species or stock of marine mammal(s).

Sec. 218.158 Renewals and modifications of letters of authorization
(LOA) and adaptive management.

(a) A letter of authorization issued under Sec. Sec. 216.106 and
218.157 of this chapter for the activity identified in Sec. 218.150(c)
shall be renewed or modified upon request of the applicant, provided
that:
(1) The proposed specified activity and mitigation, monitoring, and
reporting measures, as well as the anticipated impacts, are the same as
those described and analyzed for these regulations (excluding changes
made pursuant to the adaptive management provision of this chapter),
and;
(2) NMFS determines that the mitigation, monitoring, and reporting
measures required by the previous LOA under these regulations were
implemented.
(b) For LOA modification or renewal requests by the applicant that
include changes to the activity or the mitigation, monitoring, or
reporting (excluding changes made pursuant to the adaptive management
provision of this chapter) that do not change the findings made for the
regulations or result in no more than a minor change in the total
estimated number of takes (or distribution by species or years), NMFS
may publish a notice of proposed LOA in the Federal Register, including
the associated analysis illustrating the change, and solicit public
comment before issuing the LOA.
(c) A LOA issued under Sec. 216.106 and Sec. 218.157 of this
chapter for the activity identified in Sec. 218.154 of this chapter
may be modified by NMFS under the following circumstances:

[[Page 10023]]

(1) Adaptive management. NMFS may modify and augment the existing
mitigation, monitoring, or reporting measures (after consulting with
the Navy regarding the practicability of the modifications) if doing so
creates a reasonable likelihood of more effectively accomplishing the
goals of the mitigation and monitoring.
(i) Possible sources of data that could contribute to the decision
to modify the mitigation, monitoring, and reporting measures in an LOA:
(A) Results from Navy's monitoring from the previous year(s);
(B) Results from other marine mammal and/or sound research or
studies; or
(C) Any information that reveals marine mammals may have been taken
in a manner, extent, or number not authorized by these regulations or
subsequent LOA.
(ii) If, through adaptive management, the modifications to the
mitigation, monitoring, or reporting measures are substantial, NMFS
would publish a notice of proposed LOA in the Federal Register and
solicit public comment.
(2) Emergencies. If NMFS determines that an emergency exists that
poses a significant risk to the well-being of the species or stocks of
marine mammals specified in Sec. 218.152(c), an LOA may be modified
without prior notification and an opportunity for public comment.
Notification would be published in the Federal Register within 30 days
of the action.

[FR Doc. 2016-03622 Filed 2-25-16; 8:45 am]
BILLING CODE 3510-22-P

Category		Regulatory Information
Collection		Federal Register
sudoc Class		AE 2.7: GS 4.107: AE 2.106:
Publisher		Office of the Federal Register, National Archives and Records Administration
Section		Proposed Rules
Action		Proposed rule; request for comments and information.
Dates		Comments and information must be received no later than March 28, 2016.
Contact		John Fiorentino, Office of Protected Resources, NMFS, (301) 427-8477.
FR Citation		81 FR 9950
RIN Number		0648-BE67
CFR Associated		Exports; Fish; Imports; Incidental Take; Indians; Labeling; Marine Mammals; Navy; Penalties; Reporting and Recordkeeping Requirements; Seafood; Sonar and Transportation

81 FR 9950 - Takes of Marine Mammals Incidental to Specified Activities; U.S. Navy Training Activities in the Gulf of Alaska Temporary Maritime Activities Area

DEPARTMENT OF COMMERCENational Oceanic and Atmospheric Administration

Federal Register Volume 81, Issue 38 (February 26, 2016)

DEPARTMENT OF COMMERCE
National Oceanic and Atmospheric Administration