83 FR 37638 - Taking and Importing Marine Mammals; Taking Marine Mammals Incidental to Alaska Fisheries Science Center Fisheries Research

DEPARTMENT OF COMMERCE
National Oceanic and Atmospheric Administration

Federal Register Volume 83, Issue 148 (August 1, 2018)

Page Range		37638-37699
FR Document		2018-16114

NMFS's Office of Protected Resources (OPR) has received a request from NMFS's Alaska Fisheries Science Center (AFSC) for authorization to take marine mammals incidental to fisheries research conducted in multiple specified geographical regions, over the course of five years from the date of issuance. As required by the Marine Mammal Protection Act (MMPA), NMFS is proposing regulations to govern that take, and requests comments on the proposed regulations. NMFS will consider public comments prior to making any final decision on the issuance of the requested MMPA authorization and agency responses will be summarized in the final notice of our decision.

Federal Register, Volume 83 Issue 148 (Wednesday, August 1, 2018)

[Federal Register Volume 83, Number 148 (Wednesday, August 1, 2018)]
[Proposed Rules]
[Pages 37638-37699]
From the Federal Register Online [www.thefederalregister.org]
[FR Doc No: 2018-16114]

[[Page 37637]]

Vol. 83

Wednesday,

No. 148

August 1, 2018

Part II

Department of Commerce

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National Oceanic and Atmospheric Administration

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50 CFR Part 219

Taking and Importing Marine Mammals; Taking Marine Mammals Incidental
to Alaska Fisheries Science Center Fisheries Research; Proposed Rule

Federal Register / Vol. 83 , No. 148 / Wednesday, August 1, 2018 /
Proposed Rules

[[Page 37638]]

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DEPARTMENT OF COMMERCE

National Oceanic and Atmospheric Administration

50 CFR Part 219

[Docket No. 170127128-8546-01]
RIN 0648-BG64

Taking and Importing Marine Mammals; Taking Marine Mammals
Incidental to Alaska Fisheries Science Center Fisheries Research

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

ACTION: Proposed rule; request for comments.

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SUMMARY: NMFS's Office of Protected Resources (OPR) has received a
request from NMFS's Alaska Fisheries Science Center (AFSC) for
authorization to take marine mammals incidental to fisheries research
conducted in multiple specified geographical regions, over the course
of five years from the date of issuance. As required by the Marine
Mammal Protection Act (MMPA), NMFS is proposing regulations to govern
that take, and requests comments on the proposed regulations. NMFS will
consider public comments prior to making any final decision on the
issuance of the requested MMPA authorization and agency responses will
be summarized in the final notice of our decision.

DATES: Comments and information must be received no later than August
31, 2018.

ADDRESSES: You may submit comments on this document, identified by
NOAA-NMFS-2018-0070, by any of the following methods:
Electronic submission: Submit all electronic public
comments via the federal e-Rulemaking Portal. Go to
www.regulations.gov/#!docketDetail;D=NOAA-NMFS-2018-0070, click the
``Comment Now!'' icon, complete the required fields, and enter or
attach your comments.
Mail: Submit written 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.
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), 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: Ben Laws, Office of Protected
Resources, NMFS, (301) 427-8401.

SUPPLEMENTARY INFORMATION:

Availability

A copy of AFSC's application and any supporting documents, as well
as a list of the references cited in this document, may be obtained
online at: www.nmfs.noaa.gov/pr/permits/incidental/research.htm. In
case of problems accessing these documents, please call the contact
listed above (see FOR FURTHER INFORMATION CONTACT).

Purpose and Need for Regulatory Action

This proposed rule would establish a framework under the authority
of the MMPA (16 U.S.C. 1361 et seq.) to allow for the authorization of
take of marine mammals incidental to the AFSC's fisheries research
activities in the Gulf of Alaska, Bering Sea, and Arctic Ocean. AFSC's
request also includes fisheries research activities of the
International Pacific Halibut Commission (IPHC), which occur in the
Bering Sea, Gulf of Alaska, and off of the U.S. west coast.
We received an application from the AFSC requesting five-year
regulations and authorization to take multiple species of marine
mammals. Take would occur by Level B harassment incidental to the use
of active acoustic devices, as well as by visual disturbance of
pinnipeds, and by Level A harassment, serious injury, or mortality
incidental to the use of fisheries research gear. Please see
``Background'' below for definitions of harassment.

Legal Authority for the Proposed Action

Section 101(a)(5)(A) of the MMPA (16 U.S.C. 1371(a)(5)(A)) directs
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 for up to five years
if, after notice and public comment, the agency makes certain findings
and issues regulations that set forth permissible methods of taking
pursuant to that activity and other means of effecting the ``least
practicable adverse impact'' on the affected species or stocks and
their habitat (see the discussion below in the ``Proposed Mitigation''
section), as well as monitoring and reporting requirements. Section
101(a)(5)(A) of the MMPA and the implementing regulations at 50 CFR
part 216, subpart I provide the legal basis for issuing this proposed
rule containing five-year regulations, and for any subsequent LOAs. As
directed by this legal authority, this proposed rule contains
mitigation, monitoring, and reporting requirements.

Summary of Major Provisions Within the Proposed Rule

Following is a summary of the major provisions of this proposed
rule regarding AFSC fisheries research activities. These measures
include:
Required monitoring of the sampling areas to detect the
presence of marine mammals before deployment of certain research gear.
Required implementation of the mitigation strategy known
as the ``move-on rule mitigation protocol'' which incorporates best
professional judgment, when necessary during certain research fishing
operations.

Background

Section 101(a)(5)(A) of the MMPA (16 U.S.C. 1361 et seq.) directs
the Secretary of Commerce (as delegated to NMFS) 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, regulations are issued, and notice is
provided to the public.
An 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.
NMFS has defined ``unmitigable adverse impact'' in 50 CFR 216.103
as

[[Page 37639]]

an impact resulting from the specified activity:
(1) That is likely to reduce the availability of the species to a
level insufficient for a harvest to meet subsistence needs by: (i)
Causing the marine mammals to abandon or avoid hunting areas; (ii)
directly displacing subsistence users; or (iii) placing physical
barriers between the marine mammals and the subsistence hunters; and
(2) That cannot be sufficiently mitigated by other measures to
increase the availability of marine mammals to allow subsistence needs
to be met.
The MMPA states that the term ``take'' means to harass, hunt,
capture, kill or attempt to harass, hunt, capture, or kill any marine
mammal.
Except with respect to certain activities not pertinent here, the
MMPA defines ``harassment'' as: Any act of pursuit, torment, or
annoyance which (i) has the potential to injure a marine mammal or
marine mammal stock in the wild (Level A harassment); or (ii) has the
potential to disturb a marine mammal or marine mammal stock in the wild
by causing disruption of behavioral patterns, including, but not
limited to, migration, breathing, nursing, breeding, feeding, or
sheltering (Level B harassment).

National Environmental Policy Act

To comply with the National Environmental Policy Act of 1969 (NEPA;
42 U.S.C. 4321 et seq.) and NOAA Administrative Order (NAO) 216-6A,
NMFS must evaluate our proposed action (i.e., the promulgation of
regulations and subsequent issuance of incidental take authorization)
and alternatives with respect to potential impacts on the human
environment.
Accordingly, NMFS has prepared a draft Environmental Assessment
(EA; Draft Programmatic Environmental Assessment for Fisheries and
Ecosystem Research Conducted and Funded by the Alaska Fisheries Science
Center) to consider the environmental impacts associated with the
AFSC's proposed activities as well as the issuance of the regulations
and subsequent incidental take authorization. The EA is posted online
at: www.nmfs.noaa.gov/pr/permits/incidental/research.htm. Information
in the EA, AFSC's application, and this notice collectively provide the
environmental information related to proposed issuance of these
regulations and subsequent incidental take authorization for public
review and comment. We will review all comments submitted in response
to this notice prior to concluding our NEPA process or making a final
decision on the request for incidental take authorization.

Summary of Request

On June 28, 2016, we received an adequate and complete request from
AFSC for authorization to take marine mammals incidental to fisheries
research activities. On October 18, 2016 (81 FR 71709), we published a
notice of receipt of AFSC's application in the Federal Register,
requesting comments and information related to the AFSC request for
thirty days. We received comments jointly from The Humane Society of
the United States and Whale and Dolphin Conservation (HSUS/WDC).
Subsequently, AFSC presented substantive revisions to the application,
including revisions to the take authorization request as well as
incorporation of the IPHC fisheries research activities. We received
this revised application, which was determined to be adequate and
complete, on September 6, 2017. We then published a notice of its
receipt in the Federal Register, requesting comments and information
for thirty days, on September 14, 2017 (82 FR 43223). We received no
comments in response to this second review period. The original
comments received from HSUS/WDC were considered in development of this
proposed rule and are available online at: www.nmfs.noaa.gov/pr/permits/incidental/research.htm.
AFSC proposes to conduct fisheries research using trawl gear used
at various levels in the water column, hook-and-line gear (including
longlines with multiple hooks), gillnets, and other gear. If a marine
mammal interacts with gear deployed by AFSC, the outcome could
potentially be Level A harassment, serious injury (i.e., any injury
that will likely result in mortality), or mortality. Although any given
gear interaction could result in an outcome less severe than mortality
or serious injury, we do not have sufficient information to allow
parsing these potential outcomes. Therefore, AFSC presents a pooled
estimate of the number of potential incidents of gear interaction and,
for analytical purposes we assume that gear interactions would result
in serious injury or mortality. AFSC also uses various active acoustic
devices in the conduct of fisheries research, and use of these devices
has the potential to result in Level B harassment of marine mammals.
Level B harassment of pinnipeds hauled out may also occur, as a result
of visual disturbance from vessels conducting AFSC research.
AFSC requests authorization to take individuals of 19 species by
Level A harassment, serious injury, or mortality (hereafter referred to
as M/SI) and of 25 species by Level B harassment. The proposed
regulations would be valid for five years from the date of issuance.

Description of the Specified Activity

Overview

The AFSC collects a wide array of information necessary to evaluate
the status of exploited fishery resources and the marine environment.
AFSC scientists conduct fishery-independent research onboard NOAA-owned
and operated vessels or on chartered vessels. Such research may also be
conducted by cooperating scientists on non-NOAA vessels when the AFSC
helps fund the research. The AFSC proposes to administer and conduct
approximately 58 survey programs over the five-year period, within
three separate research areas (some survey programs are conducted
across more than one research area). The gear types used fall into
several categories: Towed nets fished at various levels in the water
column, longline gear, gillnets and seine nets, traps, and other gear.
Only use of trawl nets, longlines, and gillnets are likely to result in
interaction with marine mammals. Many of these surveys also use active
acoustic devices.
The Federal government has a responsibility to conserve and protect
living marine resources in U.S. waters and has also entered into a
number of international agreements and treaties related to the
management of living marine resources in international waters outside
the United States. NOAA has the primary responsibility for managing
marine finfish and shellfish species and their habitats, with that
responsibility delegated within NOAA to NMFS.
In order to direct and coordinate the collection of scientific
information needed to make informed fishery management decisions,
Congress created six regional fisheries science centers, each a
distinct organizational entity and the scientific focal point within
NMFS for region-based Federal fisheries-related research. This research
is aimed at monitoring fish stock recruitment, abundance, survival and
biological rates, geographic distribution of species and stocks,
ecosystem process changes, and marine ecological research. The AFSC is
the research arm of NMFS in the Alaska region of the United States. The
AFSC conducts research and provides scientific advice to manage
fisheries and conserve protected species in the geographic research
area described below and provides scientific information to support the
North Pacific Fishery

[[Page 37640]]

Management Council and other domestic and international fisheries
management organizations.
The IPHC, established by a convention between the governments of
Canada and the United States, is an international fisheries
organization mandated to conduct research on and management of the
stocks of Pacific halibut (Hippoglossus stenolepis) within the
Convention waters of both nations. The Northern Pacific Halibut Act of
1982 (16 U.S.C. 773), which amended the earlier Northern Pacific
Halibut Act of 1937, is the enabling legislation that gives effect to
the Convention in the United States. Although operating in U.S. waters
(and, therefore, subject to the MMPA prohibition on ``take'' of marine
mammals), the IPHC is not appropriately considered to be a U.S. citizen
(as defined by the MMPA) and cannot be issued an incidental take
authorization. For purposes of MMPA compliance, the AFSC sponsors the
IPHC research activities occurring in U.S. waters, with applicable
mitigation, monitoring, and reporting requirements conveyed to the IPHC
via Letters of Acknowledgement issued by the AFSC pursuant to the
Magnuson-Stevens Fishery Conservation and Management Act (MSA).
Fishery-independent data necessary to the management of halibut
stocks is collected using longline gear aboard chartered commercial
vessels within multiple IPHC regulatory areas, including within U.S.
waters of the Bering Sea, Gulf of Alaska, and off the U.S. west coast.
The IPHC proposes to conduct two survey programs over the five-year
period. IPHC activity and requested take authorization is described in
Appendix C of AFSC's application.

Dates and Duration

The specified activity may occur at any time during the five-year
period of validity of the proposed regulations. Dates and duration of
individual surveys are inherently uncertain, based on congressional
funding levels for the AFSC, weather conditions, or ship contingencies.
In addition, cooperative research is designed to provide flexibility on
a yearly basis in order to address issues as they arise. Some
cooperative research projects last multiple years or may continue with
modifications. Other projects only last one year and are not continued.
Most cooperative research projects go through an annual competitive
selection process to determine which projects should be funded based on
proposals developed by many independent researchers and fishing
industry participants.

Specified Geographical Region

The AFSC conducts research in Alaska within three research areas
considered to be distinct specified geographical regions: the Gulf of
Alaska Research Area (GOARA), the Bering Sea/Aleutian Islands Research
Area (BSAIRA), and the Chukchi Sea and Beaufort Sea Research Area
(CSBSRA). Please see Figures 2-1 through 2-3 in the AFSC application
for maps of the three research areas. We note here that, while the
specified geographical regions within which the AFSC operates may
extend outside of the U.S. Exclusive Economic Zone (EEZ), i.e., into
the Canadian EEZ (but not including Canadian territorial waters), the
MMPA's authority does not extend into foreign territorial waters. For
further information about the specified geographical regions, please
see the descriptions found in Sherman and Hempel (2009) and Wilkinson
et al. (2009). As referred to here, productivity refers to fixated
carbon (i.e., g C/m\2\/yr) and can be related to the carrying capacity
of an ecosystem.
The GOARA includes marine waters offshore from Canada north to
Alaska and west to longitude 170[deg] W, including marine waters in the
archipelagos of southeast Alaska, Prince William Sound, Cook Inlet,
Kodiak, and the Alaska Peninsula. The region encompasses fjord-
dominated regions out to the Alaska Panhandle as well as the North
Pacific slope and basin and is characterized by numerous islands, deep
fjords, and sheltered straits, as well as significant freshwater runoff
from numerous rivers. The major oceanographic influence on the region
is the Alaska Current, and sea ice is generally absent from the region.
Average sea surface temperatures (SST) are 1-9 [deg]C (winter) and 10-
16 [deg]C (summer), and the region is considered to be of moderately
high productivity.
The BSAIRA includes marine waters west of longitude 170[deg] W
along the Aleutian Islands chain and north to the Bering Strait,
primarily east of the international date line but also including an
area west of the date line south of the Gulf of Anadyr. The Bering Sea,
noted for its high productivity, is the world's third-largest semi-
enclosed water body. This region includes the extremely wide, gradually
sloping shelf of the Eastern Bering Sea, the narrow shelf and deep
passes along the Aleutian chain, the deep Aleutian Basin, Kamchatka
Basin and Bowers Ridge. The continental slope is incised with many
canyons before dropping to a generally flat abyssal plain. The annual
formation and retreat of sea ice through the Bering Strait and out over
the northeast shelf is a major determinant of species distribution.
Annual SST in the Bering Sea ranges from less than 2 [deg]C (winter) to
6-14 [deg]C (summer); in the Aleutian Islands annual SST ranges from 1-
10 [deg]C. Areas of note within the region include the Pribilof Islands
and Bristol Bay.
The Aleutian Islands archipelago includes approximately 150 islands
extending about 2,260 km westward from the Alaska Peninsula to the
Kamchatka Peninsula that create a partial geographic barrier to the
exchange of northern Pacific marine waters with Eastern Bering Sea
waters; net circulation flow is from the Bering Sea to the Chukchi Sea
through the Bering Strait. The Aleutian Islands continental shelf is
narrow, ranging in width on the north and south sides of the islands
from about 4 to 46 km, compared with the Eastern Bering Sea shelf,
which ranges from 600-800 km from the shore to the shelf edge. The
archipelago is adjacent to the Aleutian Trench, a subduction zone
characterized by volcanic activity and earthquake zones. Numerous
straits and passes connect the temperate North Pacific to the subpolar
Bering Sea; the unique combination of rish nutrients and underwater
volcanoes has created diverse and abundant coral habitat.
The CSBSRA includes waters of the Chukchi Sea east of the
International Date Line and the Beaufort Sea west of the U.S.-Canada
border within the U.S. EEZ. The region is a relatively shallow marginal
sea with an extensive continental shelf and is characterized by the
annual formation and deformation of sea ice. The Chukchi Sea portion is
shallow (water depths to approximately 100 m), while the Beaufort Sea
portion consists of narrow, shallow shelf descending to the Arctic
Ocean slope and plains of the deep Canada Basin. SST is less than 12
[deg]C in summer and averages 8 [deg]C in the southwest and along the
Beaufort coast. The area is considered to be of moderately high
productivity in the summer during ice melt; however, the region is
considered to be heterogeneous, with the Chukchi more productive than
the Beaufort. The ice-free zone of the summer is generally about 150-
200 km wide. However, the Arctic climate is changing significantly, and
one result of the change is a reduction in the sea ice extent in at
least some regions of the Arctic (e.g., Doney et al., 2012; Melillo et
al., 2014). Kotzebue Sound is a major coastal region here.
IPHC research activities are carried out within the BSAIRA and
GOARA but also within a fourth specified

[[Page 37641]]

geographical region, i.e., off the U.S. west coast (see Figure C-3 of
the AFSC application). The IPHC operates from 36[deg]40' N
(approximately Monterey Bay, California) at the southernmost extension
northward to the Canadian border, including U.S. waters within Puget
Sound. The California Current Large Marine Ecosystem (off the U.S. west
coast) is considered to be of moderately high productivity. SST is
fairly consistent, ranging from 9-14 [deg]C in winter and 13-15 [deg]C
in summer. Cape Mendocino represents a major biogeographic break, and
the region includes major estuaries such Puget Sound. The shelf is
generally narrow in the region, and shelf-break topography (e.g.,
underwater canyons) creates localized upwelling conditions that
concentrate nutrients into areas of high topographic relief. The
California Current determines the general hydrography off the coast of
California. The current moves south along the western coast of North
America, with extensive seasonal upwelling of colder, nutrient-rich
subsurface waters predominant in the area south of Cape Mendocino.
Significant interannual variation in productivity results from the
effects of this coastal upwelling as well as from the El Ni[ntilde]o-
Southern Oscillation and the Pacific Decadal Oscillation. Both
oscillations involve transitions from cooler, more productive
conditions to warmer, less productive conditions but over different
timescales.
IPHC conducts research within Puget Sound, which is affected by
high amounts of runoff from the Fraser River. The river plume
stimulates primary productivity, carrying nutrients northwards past
Vancouver Island year-round. Puget Sound is one of the largest
estuaries in the United States and is a place of great physical and
ecological complexity and productivity. The average surface water
temperature is 12.8 [deg]C in summer and 7.2 [deg]C in winter (Staubitz
et al., 1997), but surface waters frequently exceed 20 [deg]C in the
summer and fall. With nearly six million people (doubled since the
1960s), Puget Sound is also heavily influenced by human activity.

Detailed Description of Activities

The Federal government has a trust responsibility to protect living
marine resources in waters of the United States. These waters extend to
200 nm from the shoreline and include the EEZ. The U.S. government has
also entered into a number of international agreements and treaties
related to the management of living marine resources in international
waters outside of the EEZ (i.e., the high seas). To carry out its
responsibilities over U.S. and international waters, Congress has
enacted several statutes authorizing certain Federal agencies to
administer programs to manage and protect living marine resources.
Among these Federal agencies, NOAA has the primary responsibility for
protecting marine finfish and shellfish species and their habitats.
Within NOAA, NMFS has been delegated primary responsibility for the
science-based management, conservation, and protection of living marine
resources under statutes including the MSA, MMPA, and the Endangered
Species Act (ESA). As noted above, the IPHC conducts research in
support of halibut management under the terms of a convention between
the United States and Canada, originally ratified in 1924 and amended
most recently in 1979.
Within NMFS, six regional fisheries science centers direct and
coordinate the collection of scientific information needed to inform
fisheries management decisions. Each science center is a distinct
entity and is the scientific focal point for a particular region. AFSC
conducts research and provides scientific advice to manage fisheries
and conserve protected species in Alaska. AFSC provides scientific
information to support the North Pacific Fishery Management Council and
other domestic and international fisheries management organizations.
The AFSC collects a wide array of information necessary to evaluate
the status of exploited fishery resources and the marine environment.
AFSC scientists conduct fishery-independent research onboard NOAA-owned
and operated vessels or on chartered vessels, and some AFSC-funded
research is conducted by cooperative scientists. The AFSC proposes to
administer and conduct approximately 58 survey programs over the five-
year period, with an additional two survey programs conducted by the
IPHC.
The gear types used fall into several categories: Towed nets fished
at various levels in the water column, longline gear, gillnets and
seine nets, traps, and other gear. Only use of trawl nets, longlines,
and gillnets are likely to result in interaction with marine mammals.
Many of these surveys also use active acoustic devices. These surveys
may be conducted aboard NOAA-operated research vessels (R/V), including
the Oscar Dyson and Fairweather, the Alaska Department of Fish and
Game-operated Resolution, and assorted other small vessels owned by
AFSC, aboard vessels owned and operated by cooperating agencies and
institutions, or aboard charter vessels.
In the following discussion, we summarily describe various gear
types used by AFSC, with reference to specific fisheries and ecosystem
research activities conducted by the AFSC. This is not an exhaustive
list of gear and/or devices that may be utilized by AFSC but is
representative of gear categories and is complete with regard to all
gears with potential for interaction with marine mammals. Additionally,
relevant active acoustic devices, which are commonly used in AFSC
survey activities, are described separately in a subsequent section.
Please see Appendix A of AFSC's application for further description,
pictures, and diagrams of research gear and vessels. Full details
regarding planned research activities are provided in Tables 1-1 and C-
1 of AFSC's application, with specific gear used in association with
each research project and full detail regarding gear characteristics
and usage provided. Full detail is not repeated here.
Trawl nets--A trawl is a funnel-shaped net towed behind a boat to
capture fish. The codend (or bag) is the fine-meshed portion of the net
most distant from the towing vessel where fish and other organisms
larger than the mesh size are retained. In contrast to commercial
fishery operations, which generally use larger mesh to capture
marketable fish, research trawls often use smaller mesh to enable
estimates of the size and age distributions of fish in a particular
area. The body of a trawl net is generally constructed of relatively
coarse mesh that functions to gather schooling fish so that they can be
collected in the codend. The opening of the net, called the mouth, is
extended horizontally by large panels of wide mesh called wings. The
mouth of the net is held open by hydrodynamic force exerted on the
trawl doors attached to the wings of the net. As the net is towed
through the water, the force of the water spreads the trawl doors
horizontally apart. The top of a net is called the headrope, and the
bottom is called the footrope. Bottom trawls may use bobbins or roller
gear to protect the footrope as the net is dragged along the seabed.
The trawl net is usually deployed over the stern of the vessel and
attached with two cables (or warps) to winches on the deck of the
vessel. The cables are played out until the net reaches the fishing
depth. Trawl vessels typically travel at speeds of 2-5 kn while towing
the net for time periods up to several hours. The duration of the tow
depends on the purpose of the trawl, the catch rate, and the target
species. At the end of the tow the net is retrieved and the

[[Page 37642]]

contents of the codend are emptied onto the deck. For research
purposes, the speed and duration of the tow and the characteristics of
the net are typically standardized to allow meaningful comparisons of
data collected at different times and locations. Active acoustic
devices (described later) incorporated into the research vessel and the
trawl gear monitor the position and status of the net, speed of the
tow, and other variables important to the research design.
AFSC research trawling activities utilize pelagic (or midwater) and
surface trawls, which are designed to operate at various depths within
the water column but not to contact the seafloor, as well as bottom
trawls. Some research efforts use various commercial trawl nets
(commercial midwater trawls may be 75-136 m in width with opening
height of 10-20 m, while commercial bottom trawls may be 18-24 m in
width with 4-8 m opening height), while others use specific trawls.
Examples of the latter include the Poly Nor'eastern bottom trawl, which
has a 27.2-m headrope, 24.9-m footrope, and 5.8-m vertical opening;
otter bottom trawl with 6-m headrope; the 83-112 Eastern bottom trawl,
with 25-m headrope and 34-m footrope; Kodiak bottom trawl (3 m x 4 m x
8 m); the 20 m x 20 m Nordic 264 midwater trawl; 12 m x 12 m midwater
anchovy trawl (midwater); Cantrawl surface trawl, with 55-m width and
25-m depth; and Aleutian wing pelagic trawl, with 82.3-m footrope/
headrope and a 27.4-m vertical opening. Tow durations are typically 10-
30 min (though some experimental trawls may be conducted for much
longer, i.e., a period of hours), with tow depths dependent on the
purpose of the survey.
AFSC also uses beam trawls, a type of bottom trawl in which the
horizontal opening of the net is provided by a heavy beam mounted at
each end on guides or skids that travel along the seabed. AFSC beam
trawls are 1 m x 1m. On sandy or muddy bottoms, a series of ``tickler''
chains are strung between the skids ahead of the net to stir up the
fish from the seabed and chase them into the net. On rocky grounds,
these ticklers may be replaced with chain matting. Several trawls may
be towed, one on each side of the vessel. The trawls are towed along
the seafloor at speeds of 1 to 2 kn. In some shallow, nearshore
locations, push trawls may be used, i.e., vessels push nets.
Longline--Longline vessels fish with baited hooks attached to a
mainline (or groundline). The length of the longline and the number of
hooks depend on the species targeted, the size of the vessel, and the
purpose of the fishing activity. Hooks are attached to the mainline by
another thinner line called a gangion. The length of the gangion and
the distance between gangions depends on the purpose of the fishing
activity. Depending on the fishery, longline gear can be deployed on
the seafloor (bottom longline), in which case weights are attached to
the mainline, or near the surface of the water (pelagic longline), in
which case buoys are attached to the mainline to provide flotation and
keep the baited hooks suspended in the water. Radar reflectors, radio
transmitters, and light sources are often used to help fishers
determine the location of the longline gear prior to retrieval.
Segments of bottom longline gear, which are connected to form a single
continuous mainline, are often referred to as skates.
A commercial longline can be miles long and have thousands of hooks
attached, although longlines used for research surveys are often
shorter. However, the longline gear used for AFSC research surveys is
typically similar in scale to commercial gear, with 16-km mainlines and
7,200 hooks. IPHC gear consists of 1,800-ft (549-m) skates, with 100
hooks per skate. Three to ten skates may be fished at each sampling
station. There are no internationally-recognized standard measurements
for hook size, and a given size may be inconsistent between
manufacturers. Larger hooks, as are used in longlining, are referenced
by increasing whole numbers followed by a slash and a zero as size
increases (e.g., 1/0 up to 20/0). The numbers represent relative sizes,
normally associated with the gap (the distance from the point tip to
the shank).
The time period between deployment and retrieval of the longline
gear is the soak time. Soak time is an important parameter for
calculating fishing effort. For commercial fisheries the goal is to
optimize the soak time in order to maximize catch of the target species
while minimizing the bycatch rate and minimizing damage to target
species that may result from predation by sharks or other predators.
AFSC soak times range from 2-3 hours, while IPHC soak times are
typically 5 hours. AFSC also uses hook-and-line, i.e., rod-and-reel,
for some survey efforts, totaling approximately 240 rod-hrs per year
over 5 days.
Other nets--AFSC surveys utilize various small, fine-mesh, towed
nets designed to sample small fish and pelagic invertebrates. These
nets can be broadly categorized as small trawls (which are separated
from large trawl nets due to small trawls' discountable potential for
interaction with marine mammals; see ``Potential Effects of the
Specified Activity on Marine Mammals and their Habitat'') and plankton
nets.
1. The Tucker trawl is a medium-sized single-warp net used to study
pelagic fish and zooplankton. The Tucker trawl consists of a series of
nets that can be opened and closed sequentially via stepping motor
without retrieving the net from the fishing depth. It is designed for
deep oblique tows where up to three replicate nets can be sequentially
operated by a double release mechanism and is typically equipped with a
full suite of instruments, including inside and outside flow meters;
conductivity, temperature, and depth profilers (CTD); and pitch sensor.
2. The Multiple Opening/Closing Net and Environmental Sensing
System (MOCNESS) uses a stepping motor to sequentially control the
opening and closing of the net. The MOCNESS uses underwater and
shipboard electronics to control the device. The electronics system
continuously monitors the functioning of the nets, frame angle,
horizontal velocity, vertical velocity, volume filtered, and selected
environmental parameters, such as salinity and temperature. The MOCNESS
is used for specialized zooplankton surveys.
3. AFSC also uses various neuston nets, which are frame trawls
towed horizontally at the top of the water column in order to capture
neuston (i.e., organisms that inhabit the water's surface).
4. An epibenthic tow sled is an instrument designed to collect
organisms that live on bottom sediments. It consists of a fine mesh
net, typically 1 m x 1 m opening, attached to a rigid frame with
runners to help it move along the substrate.
The remainder of nets described here are plankton nets, which
usually consist of fine mesh attached to a weighted frame which spreads
the mouth of the net to cover a known surface area in order to sample
plankton and fish eggs from various parts of the water column.
5. Ring nets are used to capture plankton with vertical tows. These
nets consist of a circular frame and a cone-shaped net with a
collection jar at the codend. The net, attached to a labeled dropline,
is lowered into the water while maintaining the net's vertical
position. When the desired depth is reached, the net is pulled straight
up through the water column to collect the sample.
6. Bongo nets are towed through the water at an oblique angle to
sample plankton over a range of depths. Similar to ring nets, these
nets typically have a

[[Page 37643]]

cylindrical section coupled to a conical portion that tapers to a
detachable codend constructed of nylon mesh. During each plankton tow,
the bongo nets are deployed to depth and are then retrieved at a
controlled rate so that the volume of water sampled is uniform across
the range of depths. A collecting bucket, attached to the codend of the
net, is used to contain the plankton sample. Some bongo nets can be
opened and closed using remote control to enable the collection of
samples from particular depth ranges. A group of depth-specific bongo
net samples can be used to establish the vertical distribution of
zooplankton species in the water column at a site. Bongo nets are
generally used to collect zooplankton for research purposes and are not
used for commercial harvest.
Gillnets--Gillnets consist of vertical netting held in place by
floats and weights to selectively target fish of uniform size depending
on the netting size. Typical gillnets consist of monofilament, multi-
monofilament, or multifilament nylon constructed of single, double, or
triple netting/paneling of varying mesh sizes, depending on their use
and target species. A specific mesh size will catch a target species of
a limited size range, allowing this gear type to be very selective.
Some AFSC survey activities use small gillnets (10 m x 2 m) with 30-
minute set durations; however, gillnet survey activities at Little Port
Walter Marine Station in southeast Alaska use larger nets (150 ft x 15
ft (46 m x 5 m)) with longer soak times (2-4 hours).
Seine nets--Seine nets typically hang vertically in the water with
the bottom edge held down by weights and the top edge buoyed by floats.
Seine nets can be deployed from the shore as a beach seine or from a
boat and are actively fished, in comparison with gillnets which may be
similar but fish passively. AFSC uses beach seines, which are deployed
from shore to surround all fish in the nearshore area, and typically
have one end fastened to the shore while the other end is set out in a
wide arc and brought back to the beach. This may be done by hand or
with a small boat. AFSC research uses some larger beach seines (61 m x
5 m) as well as smaller nets (5 m x 2.5 m). A pole seine is a type of
beach seine deployed by hand. The net is pulled along the bottom by
hand as two or more people hold the poles and walk through the water.
Fish and other organisms are captured by walking the net towards shore
or tilting the poles backwards and lifting the net out of the water.
Traps and pots--Traps and pots are submerged, three-dimensional
devices, often baited, that permit organisms to enter the enclosure but
make escape extremely difficult or impossible. Most traps are attached
by a rope to a buoy on the surface of the water and may be deployed in
series. The trap entrance can be regulated to control the maximum size
of animal that can enter, and the size of the mesh in the body of the
trap can regulate the minimum size that is retained. In general, the
species caught depends on the type and characteristics of the pot or
trap used. AFSC uses fyke traps and crab pots of various sizes.
Fyke traps are bag-shaped nets held open by frames or hoops, often
outfitted with wings and/or leaders to guide fish towards the entrance
of the actual trap. Fyke trap wings can be set up to form a barrier
across a channel, trapping fish that attempt to proceed through the
channel. As the tide ebbs, fish eventually seek to leave the wetland
channel and are then trapped. AFSC sets fyke traps that are
approximately 40 m wide; however, these are only used in freshwater.
AFSC also uses net pens, hoop nets, and weirs for some research.
Dredge--A typical dredge consists of a mouth frame with an attached
collection bag. Fishers drag a dredge across the sea floor, either
scraping or penetrating the bottom. Scraping dredges collect target
species (e.g., oysters, scallops, clams, and mussels) in the top layer
of seafloor sediment with rakes or teeth that scoop up the substrate.
AFSC uses a six foot wide Virginia crab style dredge, which consists of
a heavy metal rectangular form bearing a toothed drag bar and a mesh
bag to collect specimens.
Conductivity, temperature, and depth profilers--A CTD profiler is
the primary research tool for determining chemical and physical
properties of seawater. A shipboard CTD is made up of a set of small
probes attached to a large (1-2 m diameter) metal rosette wheel. The
rosette is lowered through the water column on a cable, and CTD data
are observed in real time via a conducting cable connecting the CTD to
a computer on the ship. The rosette also holds a series of sampling
bottles that can be triggered to close at different depths in order to
collect a suite of water samples that can be used to determine
additional properties of the water over the depth of the CTD cast. A
standard CTD cast, depending on water depth, requires two to five hours
to complete. The data from a suite of samples collected at different
depths are often called a depth profile. Depth profiles for different
variables can be compared in order to glean information about physical,
chemical, and biological processes occurring in the water column.
Salinity, temperature, and depth data measured by the CTD instrument
are essential for characterization of seawater properties.
Tables 1-1 and C-1 of the AFSC's application provide detailed
information of all surveys planned by AFSC and IPHC; full detail is not
repeated here. We note here that IPHC survey activities do not use
active acoustic systems for data acquisition purposes. Therefore, we do
not consider the potential for Level B harassment that may result from
use of such systems other than for AFSC research programs in the GOARA,
BSAIRA, and CSBSRA. Many of these surveys also use small trawls,
plankton nets, and/or other gear; however, only gear with likely
potential for marine mammal interaction is described. Here we provide a
summary of projected annual survey effort in the different research
areas for those gears that we believe present the potential for marine
mammal interaction (Table 1). This summary is intended only to provide
a sense of the level of effort, and actual level of effort may vary
from year to year. Gear specifications vary; please see Tables 1-1 and
C-1 of AFSC's application.

Table 1--Projected Annual AFSC Survey Effort by Research Area and Gear Type
----------------------------------------------------------------------------------------------------------------
Survey type Gear type Tows/sets Duration per tow/set
----------------------------------------------------------------------------------------------------------------
GOARA
----------------------------------------------------------------------------------------------------------------
Bottom trawl.................. Poly Nor-Eastern (PNE) 59.................... 10 min.
Bottom trawl.................. Eastern otter......... 380................... 10-25 min.
Bottom trawl.................. Various (commercial).. 20-40................. 45 min to 6.5 hr.
Bottom trawl.................. To be determined...... 50.................... 20 min.
Bottom trawl.................. PNE................... 820................... 15 min.
Bottom trawl.................. PNE................... 70.................... 15-30 min.

[[Page 37644]]

Bottom trawl.................. PNE................... 20.................... 10-20 min.
Bottom trawl.................. PNE................... 20.................... variable.
Bottom trawl.................. Various (commercial).. 4-8................... 5-10 min.
Bottom trawl.................. Various (commercial).. 6-8................... 5-45 min.
Midwater trawl................ Various (commercial).. 20-40................. 45 min to 3 hr.
Midwater trawl................ Anchovy............... 50-75................. Up to 1 hr.
Midwater trawl................ Otter................. 20.................... 20 min.
Midwater trawl................ Nordic 264............ 96.................... 20 min.
Midwater trawl................ Cantrawl.............. 80.................... 30 min.
Midwater trawl................ Aleutian wing (AWT)... 140................... 10 min to 1 hr.
Gillnet....................... 10 m x 2 m............ 10.................... 30 min.
Gillnet....................... 46 m x 5 m............ 50.................... 2-4 hr.
Bottom longline............... 7,200 hooks (13/0).... 95.................... 3 hr.
Bottom longline............... < 300 hooks (13/0).... 7..................... 2 hr.
----------------------------------------------------------------------------------------------------------------
BSAIRA
----------------------------------------------------------------------------------------------------------------
Bottom trawl.................. PNE................... 420................... 15 min.
Bottom trawl.................. PNE................... 70.................... 15-30 min.
Bottom trawl.................. Bering Sea Combo 101/ Variable (average 88). 10-90 min.
130.
Bottom trawl.................. 83-112 Eastern otter.. 536................... 30 min.
Bottom trawl.................. 83-112 Eastern otter.. 15.................... variable.
Bottom trawl.................. Various (commercial).. 40-90................. 45 min to 6.5 hr
Bottom trawl.................. PNE................... 10.................... variable.
Bottom trawl.................. PNE................... 200................... 30 min.
Bottom trawl.................. To be determined...... 50.................... 20 min.
Midwater trawl................ Marinovich............ 35.................... 15-60 min.
Midwater trawl................ Cantrawl.............. 185................... 30 min.
Midwater trawl................ Various (commercial).. 40-90................. 45 min to 3 hr.
Midwater trawl................ Anchovy............... 100-125............... variable.
Midwater trawl................ AWT................... 110................... 10 min to 1 hr.
Bottom longline............... 7,200 hooks (13/0).... 75.................... 3 hr.
----------------------------------------------------------------------------------------------------------------
CSBSRA
----------------------------------------------------------------------------------------------------------------
Bottom trawl.................. 83-112 Eastern otter.. 143................... 15 min.
Midwater trawl................ Cantrawl.............. 70.................... 30 min.
----------------------------------------------------------------------------------------------------------------

Please note that Table 1 does not include projected survey effort
by IPHC. IPHC uses bottom longline gear to sample between an estimated
1,100 and 1,300 survey stations in U.S. waters per year. Although the
number of survey stations is estimated, IPHC states that the maximum
number of stations would not exceed 1,500. At each station, IPHC fishes
3-10 skates of longline gear, each with 100 hooks (16/0), for a soak
time of 5 hours at each station. Hooks are spaced at 18-ft (5.5-m)
intervals on 24- to 48-in (0.6- to 1.2-m) gangions. Survey stations are
located in water depths from 18-732 m in shelf waters. Please see
Figures C-3 through C-5 for depictions of IPHC's survey station
distribution.
IPHC also conducts survey effort in order to collect specimens of
halibut gonads on a monthly basis. Gear is not standardized for these
surveys and would be that which is typically used by the commercial
halibut and sablefish fleet. Gear differences are not expected to
differentially affect marine mammals, which interact similarly with all
of these commercial gears. IPHC requires collection of 50 male and 50
female specimens per month and estimates that this requires
approximately 50 total annual days at sea.
Description of Active Acoustic Sound Sources--This section contains
a brief technical background on sound, the characteristics of certain
sound types, and on metrics used in this proposal inasmuch as the
information is relevant to AFSC's specified activity and to a
discussion of the potential effects of the specified activity on marine
mammals found later in this document. We also describe the active
acoustic devices used by AFSC. As noted previously, IPHC does not use
active acoustic devices for data acquisition purposes. For general
information on sound and its interaction with the marine environment,
please see, e.g., Au and Hastings (2008); Richardson et al. (1995);
Urick (1983).
Sound travels in waves, the basic components of which are
frequency, wavelength, velocity, and amplitude. Frequency is the number
of pressure waves that pass by a reference point per unit of time and
is measured in Hz or cycles per second. Wavelength is the distance
between two peaks or corresponding points of a sound wave (length of
one cycle). Higher frequency sounds have shorter wavelengths than lower
frequency sounds, and typically attenuate (decrease) more rapidly,
except in certain cases in shallower water. Amplitude is the height of
the sound pressure wave or the ``loudness'' of a sound and is typically
described using the relative unit of the dB. A sound pressure level
(SPL) in dB is described as the ratio between a measured pressure and a
reference pressure (for underwater sound, this is 1 microPascal
([mu]Pa)) and is a logarithmic unit that accounts for large variations
in amplitude; therefore, a relatively small change in dB corresponds to
large changes in sound pressure. The source level (SL) represents the
SPL referenced at a distance of 1 m from the source (referenced to 1
[mu]Pa), while the received level is the SPL at the listener's position
(referenced to 1 [mu]Pa).
Root mean square (rms) is the quadratic mean sound pressure over
the

[[Page 37645]]

duration of an impulse. Root mean square is calculated by squaring all
of the sound amplitudes, averaging the squares, and then taking the
square root of the average (Urick, 1983). Root mean square accounts for
both positive and negative values; squaring the pressures makes all
values positive so that they may be accounted for in the summation of
pressure levels (Hastings and Popper, 2005). This measurement is often
used in the context of discussing behavioral effects, in part because
behavioral effects, which often result from auditory cues, may be
better expressed through averaged units than by peak pressures.
Sound exposure level (SEL; represented as dB re 1 [mu]Pa\2\-s)
represents the total energy in a stated frequency band over a stated
time interval or event, and considers both intensity and duration of
exposure. The per-pulse SEL is calculated over the time window
containing the entire pulse (i.e., 100 percent of the acoustic energy).
SEL is a cumulative metric; it can be accumulated over a single pulse,
or calculated over periods containing multiple pulses. Cumulative SEL
represents the total energy accumulated by a receiver over a defined
time window or during an event.
Peak sound pressure (also referred to as zero-to-peak sound
pressure or 0-pk) is the maximum instantaneous sound pressure
measurable in the water at a specified distance from the source and is
represented in the same units as the rms sound pressure. Another common
metric is peak-to-peak sound pressure (pk-pk), which is the algebraic
difference between the peak positive and peak negative sound pressures.
Peak-to-peak pressure is typically approximately 6 dB higher than peak
pressure (Southall et al., 2007).
When underwater objects vibrate or activity occurs, sound-pressure
waves are created. These waves alternately compress and decompress the
water as the sound wave travels. Underwater sound waves radiate in a
manner similar to ripples on the surface of a pond and may be either
directed in a beam or beams (as for the sources considered here) or may
radiate in all directions (omnidirectional sources). The compressions
and decompressions associated with sound waves are detected as changes
in pressure by aquatic life and man-made sound receptors such as
hydrophones.
Even in the absence of sound from the specified activity, the
underwater environment is typically loud due to ambient sound, which is
defined as environmental background sound levels lacking a single
source or point (Richardson et al., 1995). The sound level of a region
is defined by the total acoustical energy being generated by known and
unknown sources. These sources may include physical (e.g., wind and
waves, earthquakes, ice, atmospheric sound), biological (e.g., sounds
produced by marine mammals, fish, and invertebrates), and anthropogenic
(e.g., vessels, dredging, construction) sound. A number of sources
contribute to ambient sound, including wind and waves, which are a main
source of naturally occurring ambient sound for frequencies between 200
hertz (Hz) and 50 kilohertz (kHz) (Mitson, 1995). In general, ambient
sound levels tend to increase with increasing wind speed and wave
height. Precipitation can become an important component of total sound
at frequencies above 500 Hz, and possibly down to 100 Hz during quiet
times. Marine mammals can contribute significantly to ambient sound
levels, as can some fish and snapping shrimp. The frequency band for
biological contributions is from approximately 12 Hz to over 100 kHz.
Sources of ambient sound related to human activity include
transportation (surface vessels), dredging and construction, oil and
gas drilling and production, geophysical surveys, sonar, and
explosions. Vessel noise typically dominates the total ambient sound
for frequencies between 20 and 300 Hz. In general, the frequencies of
anthropogenic sounds are below 1 kHz; and, if higher frequency sound
levels are created, they attenuate rapidly.
The sum of the various natural and anthropogenic sound sources that
comprise ambient sound at any given location and time depends not only
on the source levels (as determined by current weather conditions and
levels of biological and human activity) but also on the ability of
sound to propagate through the environment. In turn, sound propagation
is dependent on the spatially and temporally varying properties of the
water column and sea floor, and is frequency-dependent. As a result of
the dependence on a large number of varying factors, ambient sound
levels can be expected to vary widely over both coarse and fine spatial
and temporal scales. Sound levels at a given frequency and location can
vary by 10-20 decibels (dB) from day to day (Richardson et al., 1995).
The result is that, depending on the source type and its intensity,
sound from the specified activity may be a negligible addition to the
local environment or could form a distinctive signal that may affect
marine mammals. Details of source types are described in the following
text.
Sounds are often considered to fall into one of two general types:
pulsed and non-pulsed (defined in the following). The distinction
between these two sound types is important because they have differing
potential to cause physical effects, particularly with regard to
hearing (e.g., Ward, 1997 in Southall et al., 2007). Please see
Southall et al. (2007) for an in-depth discussion of these concepts.
The distinction between these two sound types is not always obvious, as
certain signals share properties of both pulsed and non-pulsed sounds.
A signal near a source could be categorized as a pulse; but, due to
propagation effects as it moves farther from the source, the signal
duration becomes longer (e.g., Greene and Richardson, 1988).
Pulsed sound sources (e.g., airguns, explosions, gunshots, sonic
booms, impact pile driving) produce signals that are brief (typically
considered to be less than one second), broadband, atonal transients
(ANSI, 1986, 2005; Harris, 1998; NIOSH, 1998; ISO, 2003) and occur
either as isolated events or repeated in some succession. Pulsed sounds
are all characterized by a relatively rapid rise from ambient pressure
to a maximal pressure value followed by a rapid decay period that may
include a period of diminishing, oscillating maximal and minimal
pressures, and generally have an increased capacity to induce physical
injury as compared with sounds that lack these features.
Non-pulsed sounds can be tonal, narrowband, or broadband, brief or
prolonged, and may be either continuous or intermittent (ANSI, 1995;
NIOSH, 1998). Some of these non-pulsed sounds can be transient signals
of short duration but without the essential properties of pulses (e.g.,
rapid rise time). Examples of non-pulsed sounds include those produced
by vessels, aircraft, machinery operations such as drilling or
dredging, vibratory pile driving, and active sonar systems. The
duration of such sounds, as received at a distance, can be greatly
extended in a highly reverberant environment.
We use generic sound exposure thresholds of 160 dB rms SPL and 120
dB rms SPL to determine when an activity that produces impulsive or
continuous sound, respectively, might result in impacts to a marine
mammal such that a take by Level B harassment might occur. These
thresholds should be considered guidelines for estimating when
harassment may occur (i.e., when an animal is exposed to levels equal
to or exceeding the relevant criterion) in specific contexts; however,
useful contextual information that may inform our assessment of effects
is typically

[[Page 37646]]

lacking and we consider these thresholds as step functions.
As noted above, continuous sounds are those whose sound pressure
level remains above that of the ambient sound, with negligibly small
fluctuations in level, while intermittent sounds are defined as sounds
with interrupted levels of low or no sound. Thus, echosounder signals
are not continuous sounds but rather intermittent sounds. Intermittent
sounds can further be defined as either impulsive or non-impulsive.
Similar to impulsive sounds, echosounder signals have durations that
are typically very brief (< 1 sec) and have temporal characteristics
that more closely resemble those of impulsive sounds than non-impulsive
sounds, which typically have more gradual rise times and longer decays.
With regard to behavioral thresholds, we consider the temporal and
spectral characteristics of echosounder signals to more closely
resemble those of an impulse sound than a continuous sound. Therefore,
NMFS has determined that the 160-dB threshold for impulsive sources is
most appropriate for use in considering the potential effects of the
AFSC's activities.
A wide range of active acoustic devices are used in AFSC fisheries
surveys for remotely sensing bathymetric, oceanographic, and biological
features of the environment. Most of these sources involve relatively
high frequency, directional, and brief repeated signals tuned to
provide sufficient focus and resolution on specific objects. AFSC also
uses passive listening sensors (i.e., remotely and passively detecting
sound rather than producing it), which do not have the potential to
impact marine mammals. AFSC active acoustic sources include various
echosounders (e.g., multibeam systems), scientific sonar systems,
positional sonars (e.g., net sounders for determining trawl position),
and environmental sensors (e.g., current profilers).
Mid- and high-frequency underwater acoustic sources typically used
for scientific purposes operate by creating an oscillatory overpressure
through rapid vibration of a surface, using either electromagnetic
forces or the piezoelectric effect of some materials. A vibratory
source based on the piezoelectric effect is commonly referred to as a
transducer. Transducers are usually designed to excite an acoustic wave
of a specific frequency, often in a highly directive beam, with the
directional capability increasing with operating frequency. The main
parameter characterizing directivity is the beam width, defined as the
angle subtended by diametrically opposite ``half power'' (-3 dB) points
of the main lobe. For different transducers at a single operating
frequency the beam width can vary from 180[deg] (almost
omnidirectional) to only a few degrees. Transducers are usually
produced with either circular or rectangular active surfaces. For
circular transducers, the beam width in the horizontal plane (assuming
a downward pointing main beam) is equal in all directions, whereas
rectangular transducers produce more complex beam patterns with
variable beam width in the horizontal plane. Please see Zykov and Carr
(2014) for further discussion of electromechanical sound sources.
The types of active sources employed in fisheries acoustic research
and monitoring may be considered in two broad categories here (Category
1 and Category 2), based largely on their respective operating
frequency (e.g., within or outside the known audible range of marine
species) and other output characteristics (e.g., signal duration,
directivity). As described below, these operating characteristics
result in differing potential for acoustic impacts on marine mammals.
Category 1 active fisheries acoustic sources include those with
high output frequencies (>180 kHz) that are outside the known
functional hearing capability of any marine mammal. Sounds that are
above the functional hearing range of marine animals may be audible if
sufficiently loud (e.g., M[oslash]hl, 1968). However, the relative
output levels of these sources mean that they would potentially be
detectable to marine mammals at maximum distances of only a few meters,
and are highly unlikely to be of sufficient intensity to result in
behavioral harassment. These sources also generally have short duration
signals and highly directional beam patterns, meaning that any
individual marine mammal would be unlikely to even receive a signal
that would almost certainly be inaudible.
We are aware of two studies (Deng et al., 2014; Hastie et al.,
2014) demonstrating some behavioral reaction by marine mammals to
acoustic systems operating at user-selected frequencies above 200 kHz.
These studies generally indicate only that sub-harmonics could be
detectable by certain species at distances up to several hundred
meters. However, this detectability is in reference to ambient noise,
not to NMFS's established 160-dB threshold for assessing the potential
for incidental take for these sources. Source levels of the secondary
peaks considered in these studies--those within the hearing range of
some marine mammals--range from 135-166 dB, meaning that these sub-
harmonics would either be below levels likely to result in Level B
harassment or would attenuate to such a level within a few meters.
Beyond these important study details, these high-frequency (i.e.,
Category 1) sources and any energy they may produce below the primary
frequency that could be audible to marine mammals would be dominated by
a few primary sources that are operated near-continuously, and the
potential range above threshold would be so small as to essentially
discount them. Therefore, Category 1 sources are not expected to have
any effect on marine mammals. Further, recent sound source verification
testing of these and other similar systems did not observe any sub-
harmonics in any of the systems tested under controlled conditions
(Crocker and Fratantonio, 2016). While this can occur during actual
operations, the phenomenon may be the result of issues with the system
or its installation on a vessel rather than an issue that is inherent
to the output of the system. Category 1 sources are not considered
further in this document.
Category 2 acoustic sources, which are present on most AFSC fishery
research vessels, include a variety of single, dual, and multi-beam
echosounders (many with a variety of modes), sources used to determine
the orientation of trawl nets, and several current profilers with lower
output frequencies than Category 1 sources. Category 2 active acoustic
sources have moderate to high output frequencies (10 to 180 kHz) that
are generally within the functional hearing range of marine mammals and
therefore have the potential to cause behavioral harassment. However,
while likely potentially audible to certain species, these sources have
generally short ping durations and are typically focused (highly
directional) to serve their intended purpose of mapping specific
objects, depths, or environmental features. These characteristics
reduce the likelihood of an animal receiving or perceiving the signal.
A number of these sources, particularly those with relatively lower
output frequencies coupled with higher output levels can be operated in
different output modes (e.g., energy can be distributed among multiple
output beams) that may lessen the likelihood of perception by and
potential impact on marine mammals.
We now describe specific acoustic sources used by AFSC. The
acoustic system used during a particular survey is optimized for
surveying under specific environmental conditions (e.g., depth and
bottom type). Lower frequencies of sound travel further in

[[Page 37647]]

the water (i.e., good range) but provide lower resolution (i.e., are
less precise). Pulse width and power may also be adjusted in the field
to accommodate a variety of environmental conditions. Signals with a
relatively long pulse width travel further and are received more
clearly by the transducer (i.e., good signal-to-noise ratio) but have a
lower range resolution. Shorter pulses provide higher range resolution
and can detect smaller and more closely spaced objects in the water.
Similarly, higher power settings may decrease the utility of collected
data. Power level is also adjusted according to bottom type, as some
bottom types have a stronger return and require less power to produce
data of sufficient quality. Power is typically set to the lowest level
possible in order to receive a clear return with the best data. Survey
vessels may be equipped with multiple acoustic systems; each system has
different advantages that may be utilized depending on the specific
survey area or purpose. In addition, many systems may be operated at
one of two frequencies or at a range of frequencies. Primary source
categories are described below, and characteristics of representative
predominant sources are summarized in Table 2. Predominant sources are
those that, when operated, would be louder than and/or have a larger
acoustic footprint than other concurrently operated sources, at
relevant frequencies.
(1) Multi-Frequency Narrow Beam Scientific Echosounders--
Echosounders and sonars work by transmitting acoustic pulses into the
water that travel through the water column, reflect off the seafloor,
and return to the receiver. Water depth is measured by multiplying the
time elapsed by the speed of sound in water (assuming accurate sound
speed measurement for the entire signal path), while the returning
signal itself carries information allowing ``visualization'' of the
seafloor. Multi-frequency split-beam sensors are deployed from AFSC
survey vessels to acoustically map the distributions and estimate the
abundances and biomasses of many types of fish; characterize their
biotic and abiotic environments; investigate ecological linkages; and
gather information about their schooling behavior, migration patterns,
and avoidance reactions to the survey vessel. The use of multiple
frequencies allows coverage of a broad range of marine acoustic survey
activity, ranging from studies of small plankton to large fish schools
in a variety of environments from shallow coastal waters to deep ocean
basins. Simultaneous use of several discrete echosounder frequencies
facilitates accurate estimates of the size of individual fish, and can
also be used for species identification based on differences in
frequency-dependent acoustic backscattering between species.
(2) Multibeam Echosounder and Sonar--Multibeam echosounders and
sonars operate similarly to the devices described above. However, the
use of multiple acoustic ``beams'' allows coverage of a greater area
compared to single beam sonar. The sensor arrays for multibeam
echosounders and sonars are usually mounted on the keel of the vessel
and have the ability to look horizontally in the water column as well
as straight down. Multibeam echosounders and sonars are used for
mapping seafloor bathymetry, estimating fish biomass, characterizing
fish schools, and studying fish behavior.
(3) Single-Frequency Omnidirectional Sonar--These sources provide
omnidirectional imaging around the source with different vertical
beamwidths available, which results in differential transmitting beam
patterns. The cylindrical multi-element transducer allows the
omnidirectional sonar beam to be electronically tilted down to -
90[deg], allowing automatic tracking of schools of fish within the
entire water volume around the vessel.
(4) Acoustic Doppler Current Profiler (ADCP)--An ADCP is a type of
sonar used for measuring water current velocities simultaneously at a
range of depths. Whereas current depth profile measurements in the past
required the use of long strings of current meters, the ADCP enables
measurements of current velocities across an entire water column. The
ADCP measures water currents with sound, using the Doppler effect. A
sound wave has a higher frequency when it moves towards the sensor
(blue shift) than when it moves away (red shift). The ADCP works by
transmitting ``pings'' of sound at a constant frequency into the water.
As the sound waves travel, they ricochet off particles suspended in the
moving water, and reflect back to the instrument. Due to the Doppler
effect, sound waves bounced back from a particle moving away from the
profiler have a slightly lowered frequency when they return. Particles
moving toward the instrument send back higher frequency waves. The
difference in frequency between the waves the profiler sends out and
the waves it receives is called the Doppler shift. The instrument uses
this shift to calculate how fast the particle and the water around it
are moving. Sound waves that hit particles far from the profiler take
longer to come back than waves that strike close by. By measuring the
time it takes for the waves to return to the sensor, and the Doppler
shift, the profiler can measure current speed at many different depths
with each series of pings.
An ADCP anchored to the seafloor can measure current speed not just
at the bottom, but at equal intervals to the surface. An ADCP
instrument may be anchored to the seafloor or can be mounted to a
mooring or to the bottom of a boat. ADCPs that are moored need an
anchor to keep them on the bottom, batteries, and a data logger.
Vessel-mounted instruments need a vessel with power, a shipboard
computer to receive the data, and a GPS navigation system so the ship's
movements can be subtracted from the current velocity data. ADCPs
operate at frequencies between 75 and 300 kHz.
(5) Net Monitoring Systems--During trawling operations, a range of
sensors may be used to assist with controlling and monitoring gear. Net
sounders give information about the concentration of fish around the
opening to the trawl, as well as the clearances around the opening and
the bottom of the trawl; catch sensors give information about the rate
at which the codend is filling; symmetry sensors give information about
the optimal geometry of the trawls; and tension sensors give
information about how much tension is in the warps and sweeps.

Table 2--Operating Characteristics of Representative Predominant AFSC Active Acoustic Sources
--------------------------------------------------------------------------------------------------------------------------------------------------------
Single ping duration
Active acoustic system Operating frequencies Maximum source (ms) and repetition rate Orientation/ Nominal
level (Hz) directionality beamwidth
--------------------------------------------------------------------------------------------------------------------------------------------------------
Simrad EK60 narrow beam 18, 38, 70, 120, 200 kHz.. 226.7 dB........... 1 ms at 1 Hz............ Downward looking......... 11[deg]
echosounder.

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Simrad ME70 narrow beam 70 kHz.................... 226.7 dB........... 1 ms at 1 Hz............ Downward looking......... 11[deg]
echosounder.
Simrad ES60 multibeam echosounder. 38 and 120 kHz............ 226.6 dB........... 1 ms at 1 Hz............ Downward looking......... 7[deg]
Reson 7111 multibeam echosounder.. 38, 50, 100, 180, 300 kHz. 230 dB............. not provided............ Downward looking......... 150[deg]
--------------------------------------------------------------------------------------------------------------------------------------------------------

Description of Marine Mammals in the Area of the Specified Activity

We have reviewed AFSC's species descriptions--which summarize
available information regarding status and trends, distribution and
habitat preferences, behavior and life history, and auditory
capabilities of the potentially affected species--for accuracy and
completeness and refer the reader to Sections 3 and 4 of AFSC's
application (and Sections 3 and 4 of Appendix C, which specifically
addresses the IPHC activities), instead of reprinting the information
here. Additional information regarding population trends and threats
may be found in NMFS's Stock Assessment Reports (SAR;
www.nmfs.noaa.gov/pr/sars/) and more general information about these
species (e.g., physical and behavioral descriptions) may be found on
NMFS's website (www.nmfs.noaa.gov/pr/species/mammals/).
Table 3 lists all species with expected potential for occurrence in
the specified geographical regions where AFSC and IPHC propose to
conduct the specified activities and summarizes information related to
the population or stock, including regulatory status under the MMPA and
ESA and potential biological removal (PBR), where known. For taxonomy,
we follow Committee on Taxonomy (2017). PBR, defined by the MMPA as the
maximum number of animals, not including natural mortalities, that may
be removed from a marine mammal stock while allowing that stock to
reach or maintain its optimum sustainable population, is discussed in
greater detail later in this document (see ``Negligible Impact
Analysis'').
Marine mammal abundance estimates presented in this document
represent the total number of individuals that make up a given stock or
the total number estimated within a particular study or survey area.
NMFS's stock abundance estimates for most species represent the total
estimate of individuals within the geographic area, if known, that
comprises that stock. For some species, this geographic area may extend
beyond U.S. waters. All managed stocks in the specified geographical
regions are assessed in either NMFS's U.S. Alaska SARs or U.S. Pacific
SARs. All values presented in Table 3 are the most recent available at
the time of writing and are available in the 2016 SARs (Carretta et
al., 2017; Muto et al., 2017) or draft 2017 SARs (available online at:
www.fisheries.noaa.gov/national/marine-mammal-protection/draft-marine-mammal-stock-assessment-reports).
Forty species (with 88 managed stocks) are considered to have the
potential to co-occur with AFSC and IPHC activities. Species that could
potentially occur in the proposed research areas but are not expected
to have the potential for interaction with AFSC research gear or that
are not likely to be harassed by AFSC's use of active acoustic devices
are described briefly but omitted from further analysis. These include
extralimital species, which are species that do not normally occur in a
given area but for which there are one or more occurrence records that
are considered beyond the normal range of the species. The only species
considered to be extralimital here are the narwhal (Monodon monoceros;
CSBSRA only) and the Bryde's whale (Balaenoptera edeni brydei; IPHC
U.S. west coast research area only). In addition, the sea otter is
found in coastal waters--with the northern (or eastern) sea otter
(Enhydra lutris kenyoni) found in Alaska--and the Pacific walrus
(Odobenus rosmarus divergens) and polar bear (Ursus maritimus) may also
occur in AFSC research areas. However, these species are managed by the
U.S. Fish and Wildlife Service and are not considered further in this
document.
Two populations of gray whales are recognized, eastern and western
North Pacific (ENP and WNP). WNP whales are known to feed in the
Okhotsk Sea and off of Kamchatka before migrating south to poorly known
wintering grounds, possibly in the South China Sea. The two populations
have historically been considered geographically isolated from each
other; however, data from satellite-tracked whales indicate that there
is some overlap between the stocks. Two WNP whales were tracked from
Russian foraging areas along the Pacific rim to Baja California (Mate
et al., 2011), and, in one case where the satellite tag remained
attached to the whale for a longer period, a WNP whale was tracked from
Russia to Mexico and back again (IWC, 2012). Between 22-24 WNP whales
are known to have occurred in the eastern Pacific through comparisons
of ENP and WNP photo-identification catalogs (IWC, 2012; Weller et al.,
2011; Burdin et al., 2011). Urban et al. (2013) compared catalogs of
photo-identified individuals from Mexico with photographs of whales off
Russia and reported a total of 21 matches. Therefore, a portion of the
WNP population is assumed to migrate, at least in some years, to the
eastern Pacific during the winter breeding season.
However, the AFSC does not believe that any gray whale (WNP or ENP)
would be likely to interact with its research gear, as it is extremely
unlikely that a gray whale in close proximity to AFSC research activity
would be one of the few WNP whales that have been documented in the
eastern Pacific. The likelihood that a WNP whale would interact with
AFSC research gear is insignificant and discountable, and WNP gray
whales are omitted from further analysis.
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Prior to 2016, humpback whales were listed under the ESA as an
endangered species worldwide. Following a 2015 global status review
(Bettridge et al.,

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2015), NMFS established 14 distinct population segments (DPS) with
different listing statuses (81 FR 62259; September 8, 2016) pursuant to
the ESA. The DPSs that occur in U.S. waters do not necessarily equate
to the existing stocks designated under the MMPA and shown in Table 3.
Because MMPA stocks cannot be portioned, i.e., parts managed as ESA-
listed while other parts managed as not ESA-listed, until such time as
the MMPA stock delineations are reviewed in light of the DPS
designations, NMFS considers the existing humpback whale stocks under
the MMPA to be endangered and depleted for MMPA management purposes
(e.g., selection of a recovery factor, stock status).
Within Alaska and U.S. west coast waters, four current DPSs may
occur: The Western North Pacific (WNP) DPS (endangered), Hawaii DPS
(not listed), Mexico DPS (threatened), and Central America DPS
(endangered). According to Wade et al. (2016), in the Aleutian Islands
and Bering, Chukchi, and Beaufort Seas, encountered whales are most
likely to be from the Hawaii DPS (86.5 percent), but could be from the
Mexico DPS (11.3 percent) or WNP DPS (4.4 percent). The same pattern
holds in the Gulf of Alaska, with the probability of encountering
whales from these same DPSs expected to be 89 percent, 10.5 percent,
and 0.5 percent, respectively, and in southeast Alaska (93.9 percent
from Hawaii DPS and 6.1 percent from Mexico DPS). Off of Washington,
whales remain most likely to be from the Hawaii DPS (52.9 percent), but
are almost equally likely to be from the Mexico DPS (41.9 percent), and
could also be from the Central America DPS (14.7 percent). Off of
Oregon and California, whales are most likely to be from the Mexico DPS
(89.6 percent), with a 19.7 percent probability of an encountered whale
being from the Central America DPS. Note that these probabilities
reflect the upper limit of the 95 percent confidence interval of the
probability of occurrence; therefore, numbers may not sum to 100
percent for a given area.
Although no comprehensive abundance estimate is available for the
Alaska stock of minke whales, recent surveys provide estimates for
portions of the stock's range. A 2010 survey conducted on the eastern
Bering Sea shelf produced a provisional abundance estimate of 2,020 (CV
= 0.73) whales (Friday et al., 2013). This estimate is considered
provisional because it has not been corrected for animals missed on the
trackline, animals submerged when the ship passed, or responsive
movement. Additionally, line-transect surveys were conducted in shelf
and nearshore waters (within 30-45 nautical miles of land) in 2001-2003
between the Kenai Peninsula (150[deg] W) and Amchitka Pass (178[deg]
W). Minke whale abundance was estimated to be 1,233 (CV = 0.34) for
this area (also not been corrected for animals missed on the trackline)
(Zerbini et al., 2006). The majority of the sightings were in the
Aleutian Islands, rather than in the Gulf of Alaska, and in water
shallower than 200 m. These estimates cannot be used as an estimate of
the entire Alaska stock of minke whales because only a portion of the
stock's range was surveyed. Similarly, although a comprehensive
abundance estimate is not available for the northeast Pacific stock of
fin whales, provisional estimates representing portions of the range
are available. The same 2010 survey of the eastern Bearing sea shelf
provided an estimate of 1,061 (CV = 0.38) fin whales (Friday et al.,
2013). The estimate is not corrected for missed animals, but is
expected to be robust as previous studies have shown that only small
correction factors are needed for fin whales (Barlow, 1995). Zerbini et
al. (2006) produced an estimate of 1,652 (95% CI: 1,142-2,389) fin
whales for the area described above.
Current and historical estimates of the abundance of sperm whales
in the North Pacific are considered unreliable, and caution should be
exercised in interpreting published estimates (Muto et al., 2017).
However, Kato and Miyashita (1998) produced an abundance estimate of
102,112 (CV = 0.155) sperm whales in the western North Pacific
(believed to be positively biased). The number of sperm whales
occurring within Alaska waters is unknown.
Using 2010-2012 survey data for the inland waters of southeast
Alaska, Dahlheim et al. (2015) calculated a combined abundance estimate
for harbor porpoise in the northern (including Cross Sound, Icy Strait,
Glacier Bay, Lynn Canal, Stephens Passage, and Chatham Strait) and
southern (including Frederick Sound, Sumner Strait, Wrangell and
Zarembo Islands, and Clarence Strait as far south as Ketchikan) regions
of the inland waters of 975 (CV = 0.1). Because this abundance estimate
has not been corrected for detection biases, which are expected to be
high for harbor porpoise, the estimate is likely conservative (Muto et
al., 2017). However, this estimate may be used to calculate a minimum
abundance estimate of 896 harbor porpoise for the area, with a
corresponding PBR value of 8.9.
No estimate of population abundance is available for the entire
Alaska stock of bearded seals (note that this stock corresponds with
the Beringia DPS designated pursuant to the ESA and listed as
threatened). However, during 2012-2013, U.S. and Russian researchers
conducted aerial abundance and distribution surveys over the entire
Bering Sea and Sea of Okhotsk (Moreland et al. 2013). A sub-sample of
data from the U.S. portion of the Bering Sea were analyzed by Conn et
al. (2014) to produce an abundance estimate of approximately 299,174
(95% CI: 245,476-360,544) bearded seals in U.S. waters. However, this
estimate does not include seals that were in the Chukchi and Beaufort
seas at the time of the surveys and therefore must be considered an
underestimate. Using this estimate, a minimum abundance of 273,676
seals in the U.S. sector of the Bering Sea (and associated PBR of
8,210) was calculated.
Most taxonomists recognize five subspecies of ringed seals. The
Arctic ringed seal subspecies occurs in the Arctic Ocean and Bering Sea
and is the only stock that occurs in U.S. waters (referred to as the
Alaska stock). NMFS listed the Arctic ringed seal subspecies as
threatened under the ESA on December 28, 2012 (77 FR 76706), primarily
due to anticipated loss of sea ice through the end of the 21st century
due to ongoing climate change. On March 11, 2016, the U.S. District
Court for the District of Alaska issued a memorandum decision in a
lawsuit challenging the listing of ringed seals under the ESA (Alaska
Oil and Gas Association, et al. v. National Marine Fisheries Service,
et al., Case No. 4:14-cv-00029-RRB). The decision vacated NMFS's
listing of the Arctic subspecies of ringed seals as a threatened
species. NMFS appealed that decision and on February 12, 2018, the
Ninth Circuit U.S. Court of Appeals upheld the decision to list the
ringed seal as threatened. The decision was affirmed and the listing
reinstated on May 15, 2018.
A comprehensive and reliable abundance estimate for the Alaska
stock of ringed seals is not available. However, using data from
surveys in the late 1990s and 2000 (Bengtson et al., 2005; Frost et
al., 2004), Kelly et al. (2010) estimated the total population in the
Alaska Chukchi and Beaufort seas to be at least 300,000 ringed seals.
This is likely an underestimate since surveys in the Beaufort Sea were
limited to within 40 km from shore (Muto et al., 2017). Using the same
survey data described above for bearded seals, Conn et al. (2014)
calculated an abundance estimate of about 170,000 ringed seals for the
U.S. portion of the Bering Sea. This

[[Page 37656]]

estimate did not account for availability bias and did not include
ringed seals in the shorefast ice zone, which were surveyed using a
different method. Thus, the actual number of ringed seals in the U.S.
sector of the Bering Sea is likely much higher, perhaps by a factor of
two or more (Muto et al., 2017).
Take Reduction Planning--Take reduction plans are designed to help
recover and prevent the depletion of strategic marine mammal stocks
that interact with certain U.S. commercial fisheries, as required by
Section 118 of the MMPA. The immediate goal of a take reduction plan is
to reduce, within six months of its implementation, the M/SI of marine
mammals incidental to commercial fishing to less than the PBR level.
The long-term goal is to reduce, within five years of its
implementation, the M/SI of marine mammals incidental to commercial
fishing to insignificant levels, approaching a zero serious injury and
mortality rate, taking into account the economics of the fishery, the
availability of existing technology, and existing state or regional
fishery management plans. Take reduction teams are convened to develop
these plans.
There are no take reduction plans currently in effect for Alaskan
fisheries. For marine mammals off the U.S. west coast, there is
currently one take reduction plan in effect (Pacific Offshore Cetacean
Take Reduction Plan). The goal of this plan is to reduce M/SI of
several marine mammal stocks incidental to the California thresher
shark/swordfish drift gillnet fishery (CA DGN). A team was convened in
1996 and a final plan produced in 1997 (62 FR 51805; October 3, 1997).
Marine mammal stocks of concern initially included the California,
Oregon, and Washington stocks for beaked whales, short-finned pilot
whales, pygmy sperm whales, sperm whales, and humpback whales. The most
recent five-year averages of M/SI for these stocks are below PBR. More
information is available online at: www.nmfs.noaa.gov/pr/interactions/trt/poctrp.htm. Of the stocks of concern, the AFSC has requested the
authorization of incidental M/SI for the short-finned pilot whale only
(on behalf of IPHC; see ``Estimated Take'' later in this document). The
most recent reported average annual human-caused mortality for short-
finned pilot whales (2010-14) is 1.2 animals. The IPHC does not use
drift gillnets in its fisheries research program; therefore, take
reduction measures applicable to the CA DGN fisheries are not relevant.
Unusual Mortality Events (UME)--A UME is defined under the MMPA as
``a stranding that is unexpected; involves a significant die-off of any
marine mammal population; and demands immediate response.'' From 1991
to the present, there have been 19 formally recognized UMEs on the U.S.
west coast or in Alaska involving species under NMFS' jurisdiction. The
only currently ongoing investigations involve Guadalupe fur seals and
California sea lions along the west coast. Increased strandings of
Guadalupe fur seals (up to eight times the historical average) have
occurred along the entire coast of California. These increased
strandings were reported beginning in January 2015 and peaked from
April through June 2015, but have remained well above average through
2017. Findings from the majority of stranded animals include
malnutrition with secondary bacterial and parasitic infections.
Beginning in January 2013, elevated strandings of California sea lion
pups were observed in southern California, with live sea lion
strandings nearly three times higher than the historical average.
Findings to date indicate that a likely contributor to the large number
of stranded, malnourished pups was a change in the availability of sea
lion prey for nursing mothers, especially sardines. These UMEs are
occurring in the same areas and the causes and mechanisms of this
remain under investigation (www.nmfs.noaa.gov/pr/health/mmume/guadalupefurseals2015.html; www.nmfs.noaa.gov/pr/health/mmume/californiasealions2013.htm; accessed November 24, 2017).
Another recent, notable UME involved large whales and occurred in
the western Gulf of Alaska and off of British Columbia, Canada.
Beginning in May 2015, elevated large whale mortalities (primarily fin
and humpback whales) occurred in the areas around Kodiak Island,
Afognak Island, Chirikof Island, the Semidi Islands, and the southern
shoreline of the Alaska Peninsula. Although most carcasses have been
non-retrievable as they were discovered floating and in a state of
moderate to severe decomposition, the UME is likely attributable to
ecological factors, i.e., the 2015 El Ni[ntilde]o, ``warm water blob,''
and the Pacific Coast domoic acid bloom. While the UME remains under
investigation at the time of this writing, the dates of the UME are
considered to be from May 22, through December 31, 2015 (western Gulf
of Alaska) and from April 23, 2015 through April 16, 2016 (British
Columbia). More information is available online at www.nmfs.noaa.gov/pr/health/mmume/large_whales_2015.html.
Additional UMEs in the past ten years include those involving
ringed, ribbon, spotted, and bearded seals (collectively ``ice seals'')
(2011; disease); harbor porpoises in California (2008; cause determined
to be ecological factors); Guadalupe fur seals in the Northwest (2007;
undetermined); large whales in California (2007; human interaction);
cetaceans in California (2007; undetermined); and harbor porpoises in
the Pacific Northwest (2006; undetermined). For more information on
UMEs, please visit: www.nmfs.noaa.gov/pr/health/mmume/events.html.

Marine Mammal Hearing

Hearing is the most important sensory modality for marine mammals
underwater, and exposure to anthropogenic sound can have deleterious
effects. To appropriately assess the potential effects of exposure to
sound, it is necessary to understand the frequency ranges marine
mammals are able to hear. Current data indicate that not all marine
mammal species have equal hearing capabilities (e.g., Richardson et
al., 1995; Wartzok and Ketten, 1999; Au and Hastings, 2008). To reflect
this, Southall et al. (2007) recommended that marine mammals be divided
into functional hearing groups based on directly measured or estimated
hearing ranges on the basis of available behavioral response data,
audiograms derived using auditory evoked potential techniques,
anatomical modeling, and other data. Note that no direct measurements
of hearing ability have been successfully completed for mysticetes
(i.e., low-frequency cetaceans). Subsequently, NMFS (2016) described
generalized hearing ranges for these marine mammal hearing groups.
Generalized hearing ranges were chosen based on the approximately 65 dB
threshold from the normalized composite audiograms, with an exception
for lower limits for low-frequency cetaceans where the result was
deemed to be biologically implausible and the lower bound from Southall
et al. (2007) retained. The functional groups and the associated
frequencies are indicated below (note that these frequency ranges
correspond to the range for the composite group, with the entire range
not necessarily reflecting the capabilities of every species within
that group):
Low-frequency cetaceans (mysticetes): Generalized hearing
is estimated to occur between approximately 7 Hz and 35 kHz, with best
hearing estimated to be from 100 Hz to 8 kHz;

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Mid-frequency cetaceans (larger toothed whales, beaked
whales, and most delphinids): Generalized hearing is estimated to occur
between approximately 150 Hz and 160 kHz, with best hearing from 10 to
less than 100 kHz;
High-frequency cetaceans (porpoises, river dolphins, and
members of the genera Kogia and Cephalorhynchus; including two members
of the genus Lagenorhynchus, on the basis of recent echolocation data
and genetic data): Generalized hearing is estimated to occur between
approximately 275 Hz and 160 kHz;
Pinnipeds in water; Phocidae (true seals): Functional
hearing is estimated to occur between approximately 50 Hz to 86 kHz,
with best hearing between 1-50 kHz;
Pinnipeds in water; Otariidae (eared seals): Functional
hearing is estimated to occur between 60 Hz and 39 kHz for Otariidae,
with best hearing between 2-48 kHz.
For more detail concerning these groups and associated frequency
ranges, please see NMFS (2016) for a review of available information.
Forty marine mammal species (30 cetacean and ten pinniped (four otariid
and six phocid) species) have the potential to co-occur with AFSC and
IPHC research activities. Please refer to Table 3. Of the 30 cetacean
species that may be present, eight are classified as low-frequency
cetaceans (i.e., all mysticete species), eighteen are classified as
mid-frequency cetaceans (i.e., all delphinid and ziphiid species and
the sperm whale), and four are classified as high-frequency cetaceans
(i.e., porpoises and Kogia spp.).

Potential Effects of the Specified Activity on Marine Mammals and Their
Habitat

This section includes a summary and discussion of the ways that
components of the specified activity (e.g., gear deployment, use of
active acoustic sources, visual disturbance) may impact marine mammals
and their habitat. The ``Estimated Take'' section later in this
document includes a quantitative analysis of the number of individuals
that are expected to be taken by this activity. The ``Negligible Impact
Analysis and Determination'' section considers the content of this
section and the material it references, the ``Estimated Take'' section,
and the ``Proposed Mitigation'' section, to draw conclusions regarding
the likely impacts of these activities on the reproductive success or
survivorship of individuals and how those impacts on individuals are
likely to impact marine mammal species or stocks. In the following
discussion, we consider potential effects to marine mammals from ship
strike, physical interaction with the gear types described previously,
use of active acoustic sources, and visual disturbance of pinnipeds.

Ship Strike

Vessel collisions with marine mammals, or ship strikes, can result
in death or serious injury of the animal. Wounds resulting from ship
strike may include massive trauma, hemorrhaging, broken bones, or
propeller lacerations (Knowlton and Kraus, 2001). An animal at the
surface may be struck directly by a vessel, a surfacing animal may hit
the bottom of a vessel, or an animal just below the surface may be cut
by a vessel's propeller. Superficial strikes may not kill or result in
the death of the animal. These interactions are typically associated
with large whales, which are occasionally found draped across the
bulbous bow of large commercial ships upon arrival in port. Although
smaller cetaceans or pinnipeds are more maneuverable in relation to
large vessels than are large whales, they may also be susceptible to
strike. The severity of injuries typically depends on the size and
speed of the vessel, with the probability of death or serious injury
increasing as vessel speed increases (Knowlton and Kraus, 2001; Laist
et al., 2001; Vanderlaan and Taggart, 2007; Conn and Silber, 2013).
Impact forces increase with speed, as does the probability of a strike
at a given distance (Silber et al., 2010; Gende et al., 2011).
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
kn, and exceeded 90 percent at 17 kn. Higher speeds during collisions
result in greater force of impact, but higher speeds also appear to
increase the chance of severe injuries or death through increased
likelihood of collision by pulling whales toward the vessel (Clyne,
1999; Knowlton et al., 1995). In a separate study, Vanderlaan and
Taggart (2007) analyzed the probability of lethal mortality of large
whales at a given speed, showing that the greatest rate of change in
the probability of a lethal injury to a large whale as a function of
vessel speed occurs between 8.6 and 15 kn. The chances of a lethal
injury decline from approximately 80 percent at 15 kn to approximately
20 percent at 8.6 kn. At speeds below 11.8 kn, the chances of lethal
injury drop below fifty percent, while the probability asymptotically
increases toward one hundred percent above 15 kn.
In an effort to reduce the number and severity of strikes of the
endangered North Atlantic right whale (Eubalaena glacialis), NMFS
implemented speed restrictions in 2008 (73 FR 60173; October 10, 2008).
These restrictions require that vessels greater than or equal to 65 ft
(19.8 m) in length travel at less than or equal to 10 kn near key port
entrances and in certain areas of right whale aggregation along the
U.S. eastern seaboard. Conn and Silber (2013) estimated that these
restrictions reduced total ship strike mortality risk levels by 80 to
90 percent.
For vessels used in AFSC research activities, transit speeds
average 10 kn (but vary from 6-14 kn), while vessel speed during active
sampling with towed gear is typically only 2-4 kn. At sampling speeds,
both the possibility of striking a marine mammal and the possibility of
a strike resulting in serious injury or mortality are discountable. At
average transit speed, the probability of serious injury or mortality
resulting from a strike is less than 50 percent. However, the
likelihood of a strike actually happening is again unlikely. Ship
strikes, as analyzed in the studies cited above, generally involve
commercial shipping, which is much more common in both space and time
than is research activity. Jensen and Silber (2004) summarized ship
strikes of large whales worldwide from 1975-2003 and found that most
collisions occurred in the open ocean and involved large vessels (e.g.,
commercial shipping). Commercial fishing vessels were responsible for
three percent of recorded collisions, while only one such incident
(0.75 percent) was reported for a research vessel during that time
period.
It is possible for ship strikes to occur while traveling at slow
speeds. For example, a hydrographic survey vessel traveling at low
speed (5.5 kn) while conducting mapping surveys off the central
California coast struck and killed a blue whale in 2009. The State of
California determined that the whale had suddenly and unexpectedly
surfaced beneath the hull, with the result that the propeller severed
the whale's vertebrae, and that this was an unavoidable event. The
strike represents the only such incident in approximately 540,000 hours
of similar coastal mapping activity (p = 1.9 x 10 ^-\6\; 95%
CI = 0-5.5 x 10 ^-\6\; NMFS, 2013). In addition, a research
vessel reported a fatal strike in 2011 of a dolphin in the Atlantic,
demonstrating that it is possible for strikes involving smaller

[[Page 37658]]

cetaceans or pinnipeds to occur. In that case, the incident report
indicated that an animal apparently was struck by the vessel's
propeller as it was intentionally swimming near the vessel. While
indicative of the type of unusual events that cannot be ruled out,
neither of these instances represents a circumstance that would be
considered reasonably foreseeable or that would be considered
preventable.
Although the likelihood of vessels associated with research surveys
striking a marine mammal are low, we require a robust ship strike
avoidance protocol (see ``Proposed Mitigation''), which we believe
eliminates any foreseeable risk of ship strike. We anticipate that
vessel collisions involving AFSC research vessels, while not
impossible, represent unlikely, unpredictable events for which there
are no preventive measures. No ship strikes have been reported from any
fisheries research activities conducted or funded by the AFSC. Given
the relatively slow speeds of research vessels, the presence of bridge
crew watching for obstacles at all times (including marine mammals),
the presence of marine mammal observers on some surveys, and the small
number of research cruises relative to commercial ship traffic, we
believe that the possibility of ship strike is discountable and,
further, that were a strike of a large whale to occur, it would be
unlikely to result in serious injury or mortality. No incidental take
resulting from ship strike is anticipated, and this potential effect of
research will not be discussed further in the following analysis.

Research Gear

The types of research gear used by AFSC were described previously
under ``Detailed Description of Activity.'' Here, we broadly categorize
these gears into those whose use we consider to have an extremely
unlikely potential to result in marine mammal interaction and those
whose use we believe may result in marine mammal interaction. Gears in
the former category are not considered further, while those in the
latter category are carried forward for further analysis. Gears with
likely potential for marine mammal interaction include trawls,
longlines, and gillnets.
Trawl nets, longlines, and gillnets deployed by AFSC are similar to
gear used in various commercial fisheries, and the potential for and
history of marine mammal interaction with these gears through physical
contact (i.e., capture or entanglement) is well-documented. Read et al.
(2006) estimated marine mammal bycatch in U.S. fisheries from 1990-99
and derived an estimate of global marine mammal bycatch by expanding
U.S. bycatch estimates using data on fleet composition from the United
Nations Food and Agriculture Organization (FAO). Although most U.S.
bycatch for both cetaceans (84 percent) and pinnipeds (98 percent)
occurred in gillnets, global marine mammal bycatch in trawl nets and
longlines is likely substantial given that total global bycatch is
thought to number in the hundreds of thousands of individuals (Read et
al., 2006). In addition, global bycatch via longline has likely
increased, as longlines have become the most common method of capturing
swordfish and tuna since the U.N. banned the use of high seas driftnets
over 2.5 km long in 1991 (high seas driftnets were previously often 40-
60 km long) (Read, 2008; FAO, 2001).
Marine mammals are widely regarded as being quite intelligent and
inquisitive, and when their pursuit of prey coincides with human
pursuit of the same resources, it should be expected that physical
interaction with fishing gear may occur (e.g., Beverton, 1985).
Fishermen and marine mammals are both drawn to areas of high prey
density, and certain fishing activities may further attract marine
mammals by providing food (e.g., bait, captured fish, bycatch discards)
or by otherwise making it easier for animals to feed on a concentrated
food source. Provision of foraging opportunities near the surface may
present an advantage by negating the need for energetically expensive
deep foraging dives (Hamer and Goldsworthy, 2006). Trawling, for
example, can make available previously unexploited food resources by
gathering prey that may otherwise be too fast or deep for normal
predation, or may concentrate calories in an otherwise patchy landscape
(Fertl and Leatherwood, 1997). Pilot whales, which are generally
considered to be teuthophagous (i.e., feeding primarily on squid), were
commonly observed in association with Atlantic mackerel (Scomber
scombrus) trawl fisheries from 1977-88 in the northeast U.S. EEZ
(Waring et al., 1990). Not surprisingly, stomach contents of captured
whales were observed to have high proportions of mackerel (68 percent
of non-trace food items), indicating that the ready availability of a
novel, concentrated, high-calorie prey item resulted in changed dietary
composition (Read, 1994).
These interactions can result in injury or death for the animal(s)
involved and/or damage to fishing gear. Coastal animals, including
various pinnipeds, bottlenose dolphins, and harbor porpoises, are
perhaps the most vulnerable to these interactions and set or passive
fishing gear (e.g., gillnets, traps) the most likely to be interacted
with (e.g., Beverton, 1985; Barlow et al., 1994; Read et al., 2006;
Byrd et al., 2014; Lewison et al., 2014). Although interactions are
less common for use of trawl nets and longlines, they do occur with
sufficient frequency to necessitate the establishment of required
mitigation measures for multiple U.S. fisheries using both types of
gear (NMFS, 2017). It is likely that no species of marine mammal can be
definitively excluded from the potential for interaction with fishing
gear (e.g., Northridge, 1984); however, the extent of interactions is
likely dependent on the biology, ecology, and behavior of the species
involved and the type, location, and nature of the fishery.
Trawl Nets--As described previously, trawl nets are towed nets
(i.e., active fishing) consisting of a cone-shaped net with a codend or
bag for collecting the fish and can be designed to fish at the bottom,
surface, or any other depth in the water column. Here we refer to
bottom trawls and pelagic trawls (midwater or surface, i.e., any net
not designed to tend the bottom while fishing). Trawl nets in general
have the potential to capture or entangle marine mammals, which have
been known to be caught in bottom trawls, presumably when feeding on
fish caught therein, and in pelagic trawls, which may or may not be
coincident with their feeding (Northridge, 1984).
Capture or entanglement may occur whenever marine mammals are
swimming near the gear, intentionally (e.g., foraging) or
unintentionally (e.g., migrating), and any animal captured in a net is
at significant risk of drowning unless quickly freed. Animals can also
be captured or entangled in netting or tow lines (also called lazy
lines) other than the main body of the net; animals may become
entangled around the head, body, flukes, pectoral fins, or dorsal fin.
Interaction that does not result in the immediate death of the animal
by drowning can cause injury (i.e., Level A harassment) or serious
injury. Constricting lines wrapped around the animal can immobilize the
animal or injure by cutting into or through blubber, muscles and bone
(i.e., penetrating injuries) or constricting blood flow to or severing
appendages. Immobilization of the animal, if it does not result in
immediate drowning, can cause internal injuries from prolonged stress
and/or severe struggling and/or impede the animal's ability to feed

[[Page 37659]]

(resulting in starvation or reduced fitness) (Andersen et al., 2008).
Marine mammal interactions with trawl nets, through capture or
entanglement, are well-documented. Dolphins are known to attend
operating nets in order to either benefit from disturbance of the
bottom or to prey on discards or fish within the net. For example,
Leatherwood (1975) reported that the most frequently observed feeding
pattern for bottlenose dolphins in the Gulf of Mexico involved herds
following working shrimp trawlers, apparently feeding on organisms
stirred up from the benthos. Bearzi and di Sciara (1997)
opportunistically investigated working trawlers in the Adriatic Sea
from 1990-94 and found that ten percent were accompanied by foraging
bottlenose dolphins. However, pelagic trawls have greater potential to
capture cetaceans, because the nets may be towed at faster speeds,
these trawls are more likely to target species that are important prey
for marine mammals (e.g., squid, mackerel), and the likelihood of
working in deeper waters means that a more diverse assemblage of
species could potentially be present (Hall et al., 2000).
Globally, at least 17 cetacean species are known to feed in
association with trawlers and individuals of at least 25 species are
documented to have been killed by trawl nets, including several large
whales, porpoises, and a variety of delphinids (Perez, 2006; Young and
Iudicello, 2007; Karpouzli and Leaper, 2004; Hall et al., 2000; Fertl
and Leatherwood, 1997; Northridge, 1991; Song et al., 2010). At least
eighteen species of seals and sea lions are known to have been killed
in trawl nets (Wickens, 1995; Perez, 2006; Zeeberg et al., 2006).
Generally, direct interaction between trawl nets and marine mammals
(both cetaceans and pinnipeds) has been recorded wherever trawling and
animals co-occur. A lack of recorded interactions where animals are
known to be present may indicate simply that trawling is absent or an
insignificant component of fisheries in that region or that
interactions were not observed, recorded, or reported.
In evaluating risk relative to a specific fishery (or comparable
research survey), one must consider the size of the net as well as
frequency, timing, and location of deployment. These considerations
inform determinations of whether interaction with marine mammals is
likely. Of the net types described previously under ``Trawl Nets,''
AFSC has recorded marine mammal interactions with the Cantrawl surface
trawl net but also has one recorded interaction with a bottom trawl.
Other midwater trawl nets, such as the Nordic 264 and Cobb trawl, have
demonstrated potential for marine mammal interaction based on
interaction records from other NMFS science centers.
Longlines--Longlines are basically strings of baited hooks that are
either anchored to the bottom, for targeting groundfish, or are free-
floating, for targeting pelagic species and represent a passive fishing
technique (the latter not used by AFSC). Any longline generally
consists of a mainline from which leader lines (gangions) with baited
hooks branch off at a specified interval, and is left to passively
fish, or soak, for a set period of time before the vessel returns to
retrieve the gear. Longlines are marked by two or more floats that act
as visual markers and may also carry radio beacons; aids to detection
are of particular importance for pelagic longlines, which may drift a
significant distance from the deployment location. Bottom longlines may
be of monofilament or multifilament natural or synthetic lines.
Marine mammals may be hooked or entangled in longline gear, with
interactions potentially resulting in death due to drowning,
strangulation, severing of carotid arteries or the esophagus,
infection, an inability to evade predators, or starvation due to an
inability to catch prey (Hofmeyr et al., 2002), although it is more
likely that animals will survive being hooked if they are able to reach
the surface to breathe. Injuries, which may include serious injury,
include lacerations and puncture wounds. Animals may attempt to
depredate either bait or catch, with subsequent hooking, or may become
accidentally entangled. As described for trawls, entanglement can lead
to constricting lines wrapped around the animals and/or immobilization,
and even if entangling materials are removed the wounds caused may
continue to weaken the animal or allow further infection (Hofmeyr et
al., 2002). Large whales may become entangled in a longline and then
break free with a portion of gear trailing, resulting in alteration of
swimming energetics due to drag and ultimate loss of fitness and
potential mortality (Andersen et al., 2008). Weight of the gear can
cause entangling lines to further constrict and further injure the
animal. Hooking injuries and ingested gear are most common in small
cetaceans and pinnipeds, but have been observed in large cetaceans
(e.g., sperm whales). The severity of the injury depends on the
species, whether ingested gear includes hooks, whether the gear works
its way into the gastrointestinal (GI) tract, whether the gear
penetrates the GI lining, and the location of the hooking (e.g.,
embedded in the animal's stomach or other internal body parts)
(Andersen et al., 2008). Bottom longlines pose less of a threat to
marine mammals due to their deployment on the ocean bottom but can
still result in entanglement in buoy lines or hooking as the line is
either deployed or retrieved. The rate of interaction between longline
fisheries and marine mammals depends on the degree of overlap between
longline effort and species distribution, hook style and size, type of
bait and target catch, and fishing practices (such as setting/hauling
during the day or at night).
As was noted for trawl nets, many species of cetaceans and
pinnipeds are documented to have been killed by longlines, including
several large whales, porpoises, a variety of delphinids, seals, and
sea lions (Perez, 2006; Young and Iudicello, 2007; Northridge, 1984,
1991; Wickens, 1995). Generally, direct interaction between longlines
and marine mammals (both cetaceans and pinnipeds) has been recorded
wherever longline fishing and animals co-occur. A lack of recorded
interactions where animals are known to be present may indicate simply
that longlining is absent or an insignificant component of fisheries in
that region or that interactions were not observed, recorded, or
reported.
In evaluating risk relative to a specific fishery (or research
survey), one must consider the length of the line and number of hooks
deployed as well as frequency, timing, and location of deployment.
These considerations inform determinations of whether interaction with
marine mammals is likely. AFSC has not recorded marine mammal
interactions with any longline survey, while the IPHC has recorded five
interactions (all pinnipeds) from 1999-2016. While a lack of historical
interactions does not in and of itself indicate that future
interactions are unlikely, we believe that the historical record,
considered in context with the frequency and timing of these
activities, as well as mitigation measures employed indicate that
future marine mammal interactions with these gears would be uncommon.
Gillnets--Marine mammal interactions with gillnets are well-
documented, with a large proportion of species of all types of marine
mammals (e.g., mysticetes, odontocetes, pinnipeds) recorded as gillnet
bycatch (Reeves et al., 2013; Lewison et al., 2014; Zollett, 2009).
Reeves et al. (2013) note that numbers of marine mammals killed in
gillnets tend to be greatest for species that are widely distributed in

[[Page 37660]]

coastal and shelf waters. Because of the well-documented risk to marine
mammals, and to coastally distributed pinnipeds and small cetaceans in
particular, we believe there is some risk of interaction inherent to
AFSC use of gillnets, as described below in ``Estimated Take.''
However, this risk is limited by AFSC's minimal use of gillnets,
primarily at the Little Port Walter in southeast Alaska (see Table 1-1
of AFSC's application), and by use of pingers on gillnets as a
deterrent (see ``Proposed Mitigation'').
The AFSC also uses some traps and pots, both of which are passive
fishing gear that have limited species selectivity and may be set for
long durations (FAO, 2001). Thus, these gears have the potential to
capture non-targeted fauna that use the same habitat as targeted
species, even without the use of bait. Mortality in fyke nets can arise
from stress and injury associated with anoxia, abrasion, confinement,
and starvation (Larocque, 2011). In 2010, NMFS Northeast Fisheries
Science Center captured a harbor seal in a fyke trap. However, AFSC
fyke traps are used in freshwater habitats with only limited
deployments. Other traps and pots are likewise used in only very
limited fashion, with some traps deployed without bait. Therefore, we
do not believe that there is a reasonable potential for marine mammal
interaction with fyke traps or pots used by the AFSC, and these gears
are not considered further in this document.
Other research gear--The only AFSC research gears with any record
of marine mammal interactions are trawl nets, while IPHC has recorded
marine mammal interactions with longlines. Because of ample evidence
from commercial fishing operations, we assume that there is also risk
of marine mammal interaction due to AFSC use of gillnets. All other
gears used in AFSC fisheries research (e.g., a variety of plankton
nets, CTDs, remotely operated vehicles (ROVs)) do not have the expected
potential for marine mammal interactions and are not known to have been
involved in any marine mammal interaction anywhere. Specifically, we
consider CTDs, ROVs, small surface trawls, plankton nets, other small
nets, camera traps, dredges, and vertically deployed or towed imaging
systems to be no-impact gear types.
Unlike trawl nets, seine nets, and longline gear, which are used in
both scientific research and commercial fishing applications, these
other gears are not considered similar or analogous to any commercial
fishing gear and are not designed to capture any commercially salable
species, or to collect any sort of sample in large quantities. They are
not considered to have the potential to take marine mammals primarily
because of their design or how they are deployed. For example, CTDs are
typically deployed in a vertical cast on a cable and have no loose
lines or other entanglement hazards. A Bongo net is typically deployed
on a cable, whereas neuston nets (these may be plankton nets or small
trawls) are often deployed in the upper one meter of the water column;
either net type has very small size (e.g., two bongo nets of 0.5 m\2\
each or a neuston net of approximately 2 m\2\) and no trailing lines to
present an entanglement risk. These other gear types are not considered
further in this document.

Acoustic Effects

We previously provided general background information on sound and
the specific sources used by the AFSC (see ``Description of Active
Acoustic Sound Sources''), as well as background information on marine
mammal hearing (see ``Description of Marine Mammals in the Area of the
Specified Activity''). Here, we discuss the potential effects of AFSC
use of active acoustic sources on marine mammals.
Potential Effects of Underwater Sound--Note that, in the following
discussion, we refer in many cases to a review article concerning
studies of noise-induced hearing loss conducted from 1996-2015 (i.e.,
Finneran, 2015). For study-specific citations, please see that work.
Anthropogenic sounds cover a broad range of frequencies and sound
levels and can have a range of highly variable impacts on marine life,
from none or minor to potentially severe responses, depending on
received levels, duration of exposure, behavioral context, and various
other factors. The potential effects of underwater sound from active
acoustic sources can potentially result in one or more of the
following: Temporary or permanent hearing impairment, non-auditory
physical or physiological effects, behavioral disturbance, stress, and
masking (Richardson et al., 1995; Gordon et al., 2004; Nowacek et al.,
2007; Southall et al., 2007; G[ouml]tz et al., 2009). The degree of
effect is intrinsically related to the signal characteristics, received
level, distance from the source, and duration of the sound exposure. In
general, sudden, high level sounds can cause hearing loss, as can
longer exposures to lower level sounds. Temporary or permanent loss of
hearing will occur almost exclusively for noise within an animal's
hearing range. We first describe specific manifestations of acoustic
effects before providing discussion specific to AFSC's use of active
acoustic sources (e.g., echosounders).
Richardson et al. (1995) described zones of increasing intensity of
effect that might be expected to occur, in relation to distance from a
source and assuming that the signal is within an animal's hearing
range. First is the area within which the acoustic signal would be
audible (potentially perceived) to the animal but not strong enough to
elicit any overt behavioral or physiological response. The next zone
corresponds with the area where the signal is audible to the animal and
of sufficient intensity to elicit behavioral or physiological
responsiveness. Third is a zone within which, for signals of high
intensity, the received level is sufficient to potentially cause
discomfort or tissue damage to auditory or other systems. Overlaying
these zones to a certain extent is the area within which masking (i.e.,
when a sound interferes with or masks the ability of an animal to
detect a signal of interest that is above the absolute hearing
threshold) may occur; the masking zone may be highly variable in size.
We describe the more severe effects (i.e., permanent hearing
impairment, certain non-auditory physical or physiological effects)
only briefly as we do not expect that there is a reasonable likelihood
that AFSC use of active acoustic sources may result in such effects
(see below for further discussion). Marine mammals exposed to high-
intensity sound, or to lower-intensity sound for prolonged periods, can
experience hearing threshold shift (TS), which is the loss of hearing
sensitivity at certain frequency ranges (Finneran, 2015). TS can be
permanent (PTS), in which case the loss of hearing sensitivity is not
fully recoverable, or temporary (TTS), in which case the animal's
hearing threshold would recover over time (Southall et al., 2007).
Repeated sound exposure that leads to TTS could cause PTS. In severe
cases of PTS, there can be total or partial deafness, while in most
cases the animal has an impaired ability to hear sounds in specific
frequency ranges (Kryter, 1985).
When PTS occurs, there is physical damage to the sound receptors in
the ear (i.e., tissue damage), whereas TTS represents primarily tissue
fatigue and is reversible (Southall et al., 2007). In addition, other
investigators have suggested that TTS is within the normal bounds of
physiological variability and tolerance and does not represent physical
injury (e.g., Ward, 1997).

[[Page 37661]]

Therefore, NMFS does not consider TTS to constitute auditory injury.
Relationships between TTS and PTS thresholds have not been studied
in marine mammals, and there is no PTS data for cetaceans, but such
relationships are assumed to be similar to those in humans and other
terrestrial mammals. PTS typically occurs at exposure levels at least
several decibels above (a 40-dB threshold shift approximates PTS onset;
e.g., Kryter et al., 1966; Miller, 1974) that inducing mild TTS (a 6-dB
threshold shift approximates TTS onset; e.g., Southall et al. 2007).
Based on data from terrestrial mammals, a precautionary assumption is
that the PTS thresholds for impulse sounds (such as impact pile driving
pulses as received close to the source) are at least 6 dB higher than
the TTS threshold on a peak-pressure basis and PTS cumulative sound
exposure level thresholds are 15 to 20 dB higher than TTS cumulative
sound exposure level thresholds (Southall et al., 2007). Given the
higher level of sound or longer exposure duration necessary to cause
PTS as compared with TTS, it is considerably less likely that PTS could
occur.
Non-auditory physiological effects or injuries that theoretically
might occur in marine mammals exposed to high level underwater sound or
as a secondary effect of extreme behavioral reactions (e.g., change in
dive profile as a result of an avoidance reaction) caused by exposure
to sound include neurological effects, bubble formation, resonance
effects, and other types of organ or tissue damage (Cox et al., 2006;
Southall et al., 2007; Zimmer and Tyack, 2007). AFSC activities do not
involve the use of devices such as explosives or mid-frequency active
sonar that are associated with these types of effects.
When a live or dead marine mammal swims or floats onto shore and is
incapable of returning to sea, the event is termed a ``stranding'' (16
U.S.C. 1421h(3)). 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 (e.g., Geraci et al., 1999). However, the
cause or causes of most strandings are unknown (e.g., Best, 1982).
Combinations of dissimilar stressors may combine to kill an animal or
dramatically reduce its fitness, even though one exposure without the
other would not be expected to produce the same outcome (e.g., Sih et
al., 2004). For further description of stranding events see, e.g.,
Southall et al., 2006; Jepson et al., 2013; Wright et al., 2013.
1. Temporary Threshold Shift--TTS is the mildest form of hearing
impairment that can occur during exposure to sound (Kryter, 1985).
While experiencing TTS, the hearing threshold rises; and a sound must
be at a higher level in order to be heard. In terrestrial and marine
mammals, TTS can last from minutes or hours to days (in cases of strong
TTS). In many cases, hearing sensitivity recovers rapidly after
exposure to the sound ends. Few data on sound levels and durations
necessary to elicit mild TTS have been obtained for marine mammals.
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. 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.
Currently, TTS data only exist for four species of cetaceans
(bottlenose dolphin, beluga whale, harbor porpoise, and Yangtze finless
porpoise (Neophocoena asiaeorientalis)) and three species of pinnipeds
(northern elephant seal, harbor seal, and California sea lion) exposed
to a limited number of sound sources (i.e., mostly tones and octave-
band noise) in laboratory settings (Finneran, 2015). TTS was not
observed in trained spotted and ringed seals exposed to impulsive noise
at levels matching previous predictions of TTS onset (Reichmuth et al.,
2016). In general, harbor seals and harbor porpoises have a lower TTS
onset than other measured pinniped or cetacean species (Finneran,
2015). Additionally, the existing marine mammal TTS data come from a
limited number of individuals within these species. There are no data
available on noise-induced hearing loss for mysticetes. For summaries
of data on TTS in marine mammals or for further discussion of TTS onset
thresholds, please see Southall et al. (2007), Finneran and Jenkins
(2012), Finneran (2015), and NMFS (2016).
2. Behavioral Effects--Behavioral disturbance may include a variety
of effects, including subtle changes in behavior (e.g., minor or brief
avoidance of an area or changes in vocalizations), more conspicuous
changes in similar behavioral activities, and more sustained and/or
potentially severe reactions, such as displacement from or abandonment
of high-quality habitat. Behavioral responses to sound are highly
variable and context-specific and any reactions depend on numerous
intrinsic and extrinsic factors (e.g., species, state of maturity,
experience, current activity, reproductive state, auditory sensitivity,
time of day), as well as the interplay between factors (e.g.,
Richardson et al., 1995; Wartzok et al., 2003; Southall et al., 2007;
Weilgart, 2007; Archer et al., 2010). Behavioral reactions can vary not
only among individuals but also within an individual, depending on
previous experience with a sound source, context, and numerous other
factors (Ellison et al., 2012), and can vary depending on
characteristics associated with the sound source (e.g., whether it is
moving or stationary, number of sources, distance from the source).
Please see Appendices B-C of Southall et al. (2007) for a review of
studies involving marine mammal behavioral responses to sound.
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). Animals are most likely to habituate to
sounds that are predictable and unvarying. It is important to note that
habituation is appropriately considered as a ``progressive reduction in
response to stimuli that are perceived as neither aversive nor
beneficial,'' rather than as, more generally, moderation in response to
human disturbance (Bejder et al., 2009). The opposite process is
sensitization, when an unpleasant experience leads to subsequent
responses, often in the form of avoidance, at a lower level of
exposure. As noted, behavioral state may affect the type of response.
For example, animals that are resting may show greater behavioral
change in response to disturbing sound levels than animals that are
highly motivated to remain in an area for feeding (Richardson et al.,
1995; NRC, 2003; Wartzok et al., 2003). Controlled experiments with
captive marine mammals have showed pronounced behavioral reactions,
including avoidance of loud sound sources (Ridgway et al., 1997;
Finneran

[[Page 37662]]

et al., 2003). Observed responses of wild marine mammals to loud pulsed
sound sources (typically seismic airguns or acoustic harassment
devices) have been varied but often consist of avoidance behavior or
other behavioral changes suggesting discomfort (Morton and Symonds,
2002; see also Richardson et al., 1995; Nowacek et al., 2007). However,
many delphinids approach low-frequency seismic airgun source vessels
with no apparent discomfort or obvious behavioral change (e.g.,
Barkaszi et al., 2012), indicating the importance of frequency output
in relation to the species hearing sensitivitiy.
Available studies show wide variation in response to underwater
sound; therefore, it is difficult to predict specifically how any given
sound in a particular instance might affect marine mammals perceiving
the signal. If a marine mammal does react briefly to an underwater
sound by changing its behavior or moving a small distance, the impacts
of the change are unlikely to be significant to the individual, let
alone the stock or population. However, if a sound source displaces
marine mammals from an important feeding or breeding area for a
prolonged period, impacts on individuals and populations could be
significant (e.g., Lusseau and Bejder, 2007; Weilgart, 2007; NRC,
2005). However, there are broad categories of potential response, which
we describe in greater detail here, that include alteration of dive
behavior, alteration of foraging behavior, effects to breathing,
interference with or alteration of vocalization, avoidance, and flight.
Changes in dive behavior can vary widely and 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 (e.g., Frankel
and Clark, 2000; Costa et al., 2003; Ng and Leung, 2003; Nowacek et
al.; 2004; Goldbogen et al., 2013a, 2013b). Variations in dive behavior
may reflect interruptions in biologically significant activities (e.g.,
foraging), or they may be of little biological significance. The impact
of an alteration to dive behavior 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.
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. As for other types of behavioral response, the frequency,
duration, and temporal pattern of signal presentation, as well as
differences in species sensitivity, are likely contributing factors to
differences in response in any given circumstance (e.g., Croll et al.,
2001; Nowacek et al.; 2004; Madsen et al., 2006; Yazvenko et al.,
2007). A determination of whether foraging disruptions incur fitness
consequences would require information on or estimates of the energetic
requirements of the affected individuals and the relationship between
prey availability, foraging effort and success, and the life history
stage of the animal.
Variations in respiration naturally vary with different behaviors
and alterations to breathing 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. Various studies have shown that respiration rates may
either be unaffected or could increase, depending on the species and
signal characteristics, 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 (e.g., Kastelein et al., 2001, 2005, 2006; Gailey et
al., 2007; Gailey et al., 2016).
Marine mammals vocalize for different purposes and across multiple
modes, such as whistling, echolocation click production, calling, and
singing. Changes in vocalization behavior in response to anthropogenic
noise can occur for any of these modes and may result from a need to
compete with an increase in background noise or may reflect increased
vigilance or a startle response. For example, in the presence of
potentially masking signals, humpback whales and killer whales have
been observed to increase the length of their songs (Miller et al.,
2000; Fristrup et al., 2003; Foote et al., 2004), while 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). In some cases, animals may cease sound
production during production of aversive signals (Bowles et al., 1994).
Avoidance is the displacement of an individual from an area or
migration path as a result of the presence of a sound or other
stressors, and is one of the most obvious manifestations of disturbance
in marine mammals (Richardson et al., 1995). For example, gray whales
are known to change direction--deflecting from customary migratory
paths--in order to avoid noise from seismic airgun surveys (Malme et
al., 1984). Avoidance may be short-term, with animals returning to the
area once the noise has ceased (e.g., Bowles et al., 1994; Goold, 1996;
Stone et al., 2000; Morton and Symonds, 2002; Gailey et al., 2007).
Longer-term displacement is possible, however, which may lead to
changes in abundance or distribution patterns of the affected species
in the affected region if habituation to the presence of the sound does
not occur (e.g., Blackwell et al., 2004; Bejder et al., 2006; Teilmann
et al., 2006).
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. The flight response differs from other avoidance responses in
the intensity of the response (e.g., directed movement, rate of
travel). 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). The result of a flight response could range from
brief, temporary exertion and displacement from the area where the
signal provokes flight to, in extreme cases, marine mammal strandings
(Evans and England, 2001). However, it should be noted that response to
a perceived predator does not necessarily invoke flight (Ford and
Reeves, 2008), and whether individuals are solitary or in groups may
influence the response.
Behavioral disturbance can also impact marine mammals in more
subtle ways. Increased vigilance may result in costs related to
diversion of focus and attention (i.e., when a response consists of
increased vigilance, it may come at the cost of decreased attention to
other critical behaviors such as foraging or resting). These effects
have generally not been demonstrated for marine mammals, but studies
involving fish and terrestrial animals have shown that increased
vigilance may substantially reduce feeding rates (e.g., Beauchamp and
Livoreil, 1997; Fritz et al., 2002; Purser and Radford, 2011). In
addition, chronic disturbance can cause population declines through
reduction of fitness (e.g., decline in body condition) and subsequent
reduction in reproductive success, survival, or both (e.g., Harrington
and Veitch, 1992; Daan et al., 1996; Bradshaw et al., 1998). However,
Ridgway et al. (2006) reported that increased vigilance in bottlenose
dolphins exposed to sound over a five-

[[Page 37663]]

day period did not cause any sleep deprivation or stress effects.
Many animals perform vital functions, such as feeding, resting,
traveling, and socializing, on a diel cycle (24-hour cycle). Disruption
of such functions resulting from reactions to stressors such as sound
exposure 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 particularly severe
unless it could directly affect reproduction or survival (Southall et
al., 2007). Note that there is a difference between multi-day
substantive behavioral reactions and multi-day anthropogenic
activities. For example, just because an activity lasts for multiple
days does not necessarily mean that individual animals are either
exposed to activity-related stressors for multiple days or, further,
exposed in a manner resulting in sustained multi-day substantive
behavioral responses.
3. Stress Responses--An animal's perception of a threat may be
sufficient to trigger stress responses consisting of some combination
of behavioral responses, autonomic nervous system responses,
neuroendocrine responses, or immune responses (e.g., Seyle, 1950;
Moberg, 2000). In many cases, an animal's first and sometimes most
economical (in terms of energetic costs) response is behavioral
avoidance of the potential stressor. Autonomic nervous system responses
to stress typically involve changes in heart rate, blood pressure, and
gastrointestinal activity. These responses have a relatively short
duration and may or may not have a significant long-term effect on an
animal's fitness.
Neuroendocrine stress responses often involve the hypothalamus-
pituitary-adrenal system. Virtually all neuroendocrine 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, altered metabolism, reduced immune
competence, and behavioral disturbance (e.g., Moberg, 1987; Blecha,
2000). Increases in the circulation of glucocorticoids are also equated
with stress (Romano et al., 2004).
The primary distinction between stress (which is adaptive and does
not normally place an animal at risk) and ``distress'' is the 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 serious
fitness consequences. 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 functions. This state of
distress will last until the animal replenishes its energetic reserves
sufficient to restore normal function.
Relationships between these physiological mechanisms, animal
behavior, and the costs of stress responses are well-studied through
controlled experiments and for both laboratory and free-ranging animals
(e.g., Holberton et al., 1996; Hood et al., 1998; Jessop et al., 2003;
Krausman et al., 2004; Lankford et al., 2005). Stress responses due to
exposure to anthropogenic sounds or other stressors and their effects
on marine mammals have also been reviewed (Fair and Becker, 2000;
Romano et al., 2002b) and, more rarely, studied in wild populations
(e.g., Romano et al., 2002a). For example, 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. These
and other studies lead to a reasonable expectation that some marine
mammals will experience physiological stress responses upon exposure to
acoustic stressors and that it is possible that some of these would be
classified as ``distress.'' In addition, any animal experiencing TTS
would likely also experience stress responses (NRC, 2003).
4. Auditory Masking--Sound can disrupt behavior through masking, or
interfering with, an animal's ability to detect, recognize, or
discriminate between acoustic signals of interest (e.g., those used for
intraspecific communication and social interactions, prey detection,
predator avoidance, navigation) (Richardson et al., 1995; Erbe et al.,
2016). Masking occurs when the receipt of a sound is interfered with by
another coincident sound at similar frequencies and at similar or
higher intensity, and may occur whether the sound is natural (e.g.,
snapping shrimp, wind, waves, precipitation) or anthropogenic (e.g.,
shipping, sonar, seismic exploration) in origin. The ability of a noise
source to mask biologically important sounds depends on the
characteristics of both the noise source and the signal of interest
(e.g., signal-to-noise ratio, temporal variability, direction), in
relation to each other and to an animal's hearing abilities (e.g.,
sensitivity, frequency range, critical ratios, frequency
discrimination, directional discrimination, age or TTS hearing loss),
and existing ambient noise and propagation conditions.
Under certain circumstances, marine mammals experiencing
significant masking could also be impaired from maximizing their
performance fitness in survival and reproduction. Therefore, when the
coincident (masking) sound is man-made, it may be considered harassment
when disrupting or altering critical behaviors. It is important to
distinguish TTS and PTS, which persist after the sound exposure, from
masking, which occurs during the sound exposure. Because masking
(without resulting in TS) is not associated with abnormal physiological
function, it is not considered a physiological effect, but rather a
potential behavioral effect.
The frequency range of the potentially masking sound is important
in determining any potential behavioral impacts. For example, low-
frequency signals may have less effect on high-frequency echolocation
sounds produced by odontocetes but are more likely to affect detection
of mysticete communication calls and other potentially important
natural sounds such as those produced by surf and some prey species.
The masking of communication signals by anthropogenic noise may be
considered as a reduction in the communication space of animals (e.g.,
Clark et al., 2009) and may result in energetic or other costs as
animals change their vocalization behavior (e.g., Miller et al., 2000;
Foote et al., 2004; Parks et al., 2007; Di Iorio and Clark, 2009; Holt
et al., 2009). Masking can be reduced in situations where the signal
and noise come from different directions (Richardson et al., 1995),
through amplitude modulation of the signal, or through other
compensatory behaviors (Houser and Moore, 2014). Masking can be tested
directly in captive species (e.g., Erbe, 2008), but in wild populations
it must be either modeled or inferred from evidence of masking
compensation. There are few studies addressing real-world masking
sounds likely to be experienced by marine mammals in the wild (e.g.,
Branstetter et al., 2013).
Masking affects both senders and receivers of acoustic signals and
can potentially have long-term chronic effects on marine mammals at the
population level as well as at the individual level. Low-frequency
ambient sound levels have increased by as much as 20 dB (more than
three times in terms of SPL) in the world's ocean from pre-industrial
periods, with most of the increase from distant commercial

[[Page 37664]]

shipping (Hildebrand, 2009). All anthropogenic sound sources, but
especially chronic and lower-frequency signals (e.g., from vessel
traffic), contribute to elevated ambient sound levels, thus
intensifying masking.
Potential Effects of AFSC Activity--As described previously (see
``Description of Active Acoustic Sound Sources''), the AFSC proposes to
use various active acoustic sources, including echosounders (e.g.,
multibeam systems), scientific sonar systems, positional sonars (e.g.,
net sounders for determining trawl position), and environmental sensors
(e.g., current profilers). These acoustic sources, which are present on
most AFSC fishery research vessels, include a variety of single, dual,
and multi-beam echosounders (many with a variety of modes), sources
used to determine the orientation of trawl nets, and several current
profilers.
Many typically investigated acoustic sources (e.g., seismic
airguns, low- and mid-frequency active sonar used for military
purposes, pile driving, vessel noise)--sources for which certain of the
potential acoustic effects described above have been observed or
inferred--produce signals that are either much lower frequency and/or
higher total energy (considering output sound levels and signal
duration) than the high-frequency mapping and fish-finding systems used
by the AFSC. There has been relatively little attention given to the
potential impacts of high-frequency sonar systems on marine life,
largely because their combination of high output frequency and
relatively low output power means that such systems are less likely to
impact many marine species. However, some marine mammals do hear and
produce sounds within the frequency range used by these sources and
ambient noise is much lower at high frequencies, increasing the
probability of signal detection relative to other sounds in the
environment.
As noted above, relatively high levels of sound are likely required
to cause TTS in most pinnipeds and odontocete cetaceans. While
dependent on sound exposure frequency, level, and duration, existing
studies indicate that for the kinds of relatively brief exposures
potentially associated with transient sounds such as those produced by
the active acoustic sources used by the AFSC, SPLs in the range of
approximately 180-220 dB rms might be required to induce onset TTS
levels for most species (Southall et al., 2007). However, it should be
noted that there may be increased sensitivity to TTS for certain
species generally (harbor porpoise; Lucke et al., 2009) or specifically
at higher sound exposure frequencies, which correspond to a species'
best hearing range (20 kHz vs. 3 kHz for bottlenose dolphins; Finneran
and Schlundt, 2010). However, for these animals, which are better able
to hear higher frequencies and may be more sensitive to higher
frequencies, exposures on the order of approximately 170 dB rms or
higher for brief transient signals are likely required for even
temporary (recoverable) changes in hearing sensitivity that would
likely not be categorized as physiologically damaging (Lucke et al.,
2009). The corresponding estimates for PTS would be at very high
received levels that would rarely be experienced in practice.
Based on discussion provided by Southall et al. (2007), Lurton and
DeRuiter (2011) modeled the potential impacts of conventional
echosounders on marine mammals, estimating PTS onset at typical
distances of 10-100 m for the kinds of sources considered here. Kremser
et al. (2005) modeled the potential for TTS in blue, sperm, and beaked
whales (please see Kremser et al. (2005) for discussion of assumptions
regarding TTS onset in these species) from a multibeam echosounder,
finding similarly that TTS would likely only occur at very close ranges
to the hull of the vessel. The authors estimated ship movement at 12 kn
(faster than AFSC vessels would typically move), which would result in
an underestimate of the potential for TTS to occur, but the modeled
system (Hydrosweep) operates at lower frequencies and with a wider beam
pattern than do typical AFSC systems, which would result in a likely
more significant overestimate of TTS potential. The results of both
studies emphasize that these effects would very likely only occur in
the cone ensonified below the ship and that animal responses to the
vessel (sound or physical presence) at these extremely close ranges
would very likely influence their probability of being exposed to these
levels. At the same distances, but to the side of the vessel, animals
would not be exposed to these levels, greatly decreasing the potential
for an animal to be exposed to the most intense signals. For example,
Kremser et al. (2005) note that SPLs outside the vertical lobe, or
beam, decrease rapidly with distance, such that SPLs within the
horizontal lobes are about 20 dB less than the value found in the
center of the beam. For certain species (i.e., odontocete cetaceans and
especially harbor porpoises), these ranges may be somewhat greater
based on more recent data (Lucke et al., 2009; Finneran and Schlundt,
2010) but are likely still on the order of hundreds of meters. In
addition, potential behavioral responses further reduce the already low
likelihood that an animal may approach close enough for any type of
hearing loss to occur.
Various other studies have evaluated the environmental risk posed
by use of specific scientific sonar systems. Burkhardt et al. (2007)
considered both the Hydrosweep system evaluated by Kremser et al.
(2005) and the Simrad EK60, which is used by the AFSC, and concluded
that direct injury (i.e., sound energy causes direct tissue damage) and
indirect injury (i.e., self-damaging behavior as response to acoustic
exposure) would be unlikely given source and operational use (i.e.,
vessel movement) characteristics, and that any behavioral responses
would be unlikely to be significant. Similarly, Boebel et al. (2006)
considered the Hydrosweep system in relation to the risk for direct or
indirect injury, concluding that (1) risk of TTS (please see Boebel et
al. (2006) for assumptions regarding TTS onset) would be less than two
percent of the risk of ship strike and (2) risk of behaviorally-induced
damage would be essentially nil due to differences in source
characteristics between scientific sonars and sources typically
associated with stranding events (e.g., mid-frequency active sonar, but
see discussion of the 2008 Madagascar stranding event below). It should
be noted that the risk of direct injury may be greater when a vessel
operates sources while on station (i.e., stationary), as there is a
greater chance for an animal to receive the signal when the vessel is
not moving.
Boebel et al. (2005) report the results of a workshop in which a
structured, qualitative risk analysis of a range of acoustic technology
was undertaken, specific to use of such technology in the Antarctic.
The authors assessed a single-beam echosounder commonly used for
collecting bathymetric data (12 kHz, 232 dB, 10[deg] beam width), an
array of single-beam echosounders used for mapping krill (38, 70, 120,
and 200 kHz; 230 dB; 7[deg] beam width), and a multibeam echosounder
(30 kHz, 236 dB, 150[deg] x 1[deg] swath width). For each source, the
authors produced a matrix displaying the severity of potential
consequences (on a six-point scale) against the likelihood of
occurrence for a given degree of severity. For the former two systems,
the authors determined on the basis of the volume of water potentially
affected by the system and comparisons between its output and available
TTS data that the chance of TTS is only in a small volume immediately
under the

[[Page 37665]]

transducers, and that consequences of level four and above were
inconceivable, whereas level one consequences (``Individuals show no
response, or only a temporary (minutes) behavior change'') would be
expected in almost all instances. Some minor displacement of animals in
the immediate vicinity of the ship may occur. For the multibeam
echosounder, Boebel et al. (2005) note that the high output and broad
width of the swath abeam of the vessel makes displacement of animals
more likely. However, the fore and aft beamwidth is small and the pulse
length very short, so the risk of ensonification above TTS levels is
still considered quite small and the likelihood of auditory or other
injuries low. In general, the authors reached the same conclusions
described for the single-beam systems but note that more severe
impacts--including fatalities resulting from herding of sensitive
species in narrow seaways--are at least possible (i.e., may occur in
exceptional circumstances). However, the probability of herding remains
low not just because of the rarity of the necessary confluence of
species, bathymetry, and likely other factors, but because the
restricted beam shape makes it unlikely that an animal would be exposed
more than briefly during the passage of the vessel (Boebel et al.,
2005). More recently, Lurton (2016) conducted a modeling exercise and
concluded similarly that likely potential for acoustic injury from
these types of systems is negligible, but that behavioral response
cannot be ruled out.
We have, however, considered the potential for severe behavioral
responses such as stranding and associated indirect injury or mortality
from AFSC use of the multibeam echosounder, on the basis of a 2008 mass
stranding of approximately one hundred melon-headed whales
(Peponocephala electra) in a Madagascar lagoon system. An investigation
of the event indicated that use of a high-frequency mapping system (12-
kHz multibeam echosounder; it is important to note that all AFSC
sources operate at higher frequencies (see Table 2)) was the most
plausible and likely initial behavioral trigger of the event, while
providing the caveat that there is no unequivocal and easily
identifiable single cause (Southall et al., 2013). The panel's
conclusion was based on (1) very close temporal and spatial association
and directed movement of the survey with the stranding event; (2) the
unusual nature of such an event coupled with previously documented
apparent behavioral sensitivity of the species to other sound types
(Southall et al., 2006; Brownell et al., 2009); and (3) the fact that
all other possible factors considered were determined to be unlikely
causes. Specifically, regarding survey patterns prior to the event and
in relation to bathymetry, the vessel transited in a north-south
direction on the shelf break parallel to the shore, ensonifying large
areas of deep-water habitat prior to operating intermittently in a
concentrated area offshore from the stranding site; this may have
trapped the animals between the sound source and the shore, thus
driving them towards the lagoon system.
The investigatory panel systematically excluded or deemed highly
unlikely nearly all potential reasons for these animals leaving their
typical pelagic habitat for an area extremely atypical for the species
(i.e., a shallow lagoon system). Notably, this was the first time that
such a system has been associated with a stranding event.
The panel also noted several site- and situation-specific secondary
factors that may have contributed to the avoidance responses that led
to the eventual entrapment and mortality of the whales. Specifically,
shoreward-directed surface currents and elevated chlorophyll levels in
the area preceding the event may have played a role (Southall et al.,
2013). The report also notes that prior use of a similar system in the
general area may have sensitized the animals and also concluded that,
for odontocete cetaceans that hear well in higher frequency ranges
where ambient noise is typically quite low, high-power active sonars
operating in this range may be more easily audible and have potential
effects over larger areas than low frequency systems that have more
typically been considered in terms of anthropogenic noise impacts. It
is, however, important to note that the relatively lower output
frequency, higher output power, and complex nature of the system
implicated in this event, in context of the other factors noted here,
likely produced a fairly unusual set of circumstances that indicate
that such events would likely remain rare and are not necessarily
relevant to use of lower-power, higher-frequency systems more commonly
used for scientific applications. The risk of similar events recurring
may be very low, given the extensive use of active acoustic systems
used for scientific and navigational purposes worldwide on a daily
basis and the lack of direct evidence of such responses previously
reported.
Characteristics of the sound sources predominantly used by AFSC
further reduce the likelihood of effects to marine mammals, as well as
the intensity of effect assuming that an animal perceives the signal.
Intermittent exposures--as would occur due to the brief, transient
signals produced by these sources--require a higher cumulative SEL to
induce TTS than would continuous exposures of the same duration (i.e.,
intermittent exposure results in lower levels of TTS) (Mooney et al.,
2009a; Finneran et al., 2010). In addition, intermittent exposures
recover faster in comparison with continuous exposures of the same
duration (Finneran et al., 2010). Although echosounder pulses are, in
general, emitted rapidly, they are not dissimilar to odontocete
echolocation click trains. Research indicates that marine mammals
generally have extremely fine auditory temporal resolution and can
detect each signal separately (e.g., Au et al., 1988; Dolphin et al.,
1995; Supin and Popov, 1995; Mooney et al., 2009b), especially for
species with echolocation capabilities. Therefore, it is likely that
marine mammals would indeed perceive echosounder signals as being
intermittent.
We conclude here that, on the basis of available information on
hearing and potential auditory effects in marine mammals, high-
frequency cetacean species would be the most likely to potentially
incur temporary hearing loss from a vessel operating high-frequency
sonar sources, and the potential for PTS to occur for any species is so
unlikely as to be discountable. Even for high-frequency cetacean
species, individuals would have to make a very close approach and also
remain very close to vessels operating these sources in order to
receive multiple exposures at relatively high levels, as would be
necessary to cause TTS. Additionally, given that behavioral responses
typically include the temporary avoidance that might be expected (see
below), the potential for auditory effects considered physiological
damage (injury) is considered extremely low in relation to realistic
operations of these devices. Given the fact that fisheries research
survey vessels are moving, the likelihood that animals may avoid the
vessel to some extent based on either its physical presence or due to
aversive sound (vessel or active acoustic sources), and the
intermittent nature of many of these sources, the potential for TTS is
probably low for high-frequency cetaceans and very low to zero for
other species.
Based on the source operating characteristics, most of these
sources may be detected by odontocete cetaceans (and particularly high-

[[Page 37666]]

frequency specialists such as porpoises) but are unlikely to be audible
to mysticetes (i.e., low-frequency cetaceans) and some pinnipeds. While
low-frequency cetaceans and pinnipeds have been observed to respond
behaviorally to low- and mid-frequency sounds (e.g., Frankel, 2005),
there is little evidence of behavioral responses in these species to
high-frequency sound exposure (e.g., Jacobs and Terhune, 2002;
Kastelein et al., 2006). If a marine mammal does perceive a signal from
a AFSC active acoustic source, it is likely that the response would be,
at most, behavioral in nature. Behavioral reactions of free-ranging
marine mammals to scientific sonars are likely to vary by species and
circumstance. For example, Watkins et al. (1985) note that sperm whales
did not appear to be disturbed by or even aware of signals from
scientific sonars and pingers (36-60 kHz) despite being very close to
the transducers, but Gerrodette and Pettis (2005) report that when a
38-kHz echosounder and ADCP were on (1) the average size of detected
schools of spotted dolphins and pilot whales was decreased; (2)
perpendicular sighting distances increased for spotted and spinner
dolphins; and (3) sighting rates decreased for beaked whales.
Despite these observations, few experiments have been conducted to
explicitly test for potential effects of echosounders on the behavior
of wild cetaceans. Quick et al. (2017) describe an experimental
approach to assess potential changes in short-finned pilot whale
behavior during exposure to an echosounder (Simrad EK60 operated at 38
kHz, which is commonly used by AFSC). Previous studies of the effects
of military tactical sonars on pilot whales failed to document overt
avoidance responses, but did show changes in heading variance, which
may be indicative of avoidance (Miller et al., 2012; Quick et al.,
2017). In 2011, digital acoustic recording tags (DTAG) were attached to
pilot whales off of North Carolina, with five of the whales exposed to
signals from the echosounder over a period of eight days and four
treated as control animals. DTAGS record both received levels of noise
as well as orientation of the animal. Results did not show an overt
response to the echosounder or a change to foraging behavior of tagged
whales, but the whales did increase heading variance during exposure.
The authors suggest that this response was not a directed avoidance
response but was more likely a vigilance response, with animals
maintaining awareness of the location of the echosounder through
increased changes in heading variance (Quick et al., 2017). Visual
observations of behavior did not indicate any dramatic response,
unusual behaviors, or changes in heading, and cessation of biologically
important behavior such as feeding was not observed. These less overt
responses to sound exposure are difficult to detect by visual
observation, but may have important consequences if the exposure does
interfere with biologically important behavior. Given the transient
nature of AFSC use of active acoustic sources, we do not expect any
behavioral disturbance to carry meaningful biological consequences for
individuals.
As described above, behavioral responses of marine mammals are
extremely variable, depending on multiple exposure factors, with the
most common type of observed response being behavioral avoidance of
areas around aversive sound sources. Certain odontocete cetaceans
(particularly harbor porpoises and beaked whales) are known to avoid
high-frequency sound sources in both field and laboratory settings
(e.g., Kastelein et al., 2000, 2005, 2008a, 2008b; Culik et al., 2001;
Johnston, 2002; Olesiuk et al., 2002; Carretta et al., 2008). There is
some additional, low probability for masking to occur for high-
frequency specialists, but similar factors (directional beam pattern,
transient signal, moving vessel) mean that the significance of any
potential masking is probably inconsequential.

Potential Effects of Visual Disturbance

During AFSC surveys conducted in coastal areas, pinnipeds are
expected to be hauled out and at times experience incidental close
approaches by researchers in small vessels during the course of
fisheries research activities. AFSC expects some of these animals will
exhibit a behavioral response to the visual stimuli (e.g., including
alert behavior, movement, vocalizing, or flushing). NMFS does not
consider the lesser reactions (e.g., alert behavior) to constitute
harassment. These events are expected to be infrequent and cause only a
temporary disturbance on the order of minutes. Monitoring results from
other activities involving the disturbance of pinnipeds and relevant
studies of pinniped populations that experience more regular vessel
disturbance indicate that individually significant or population level
impacts are unlikely to occur.
In areas where disturbance of haul-outs due to periodic human
activity (e.g., researchers approaching on foot, passage of small
vessels, maintenance activity) occurs, monitoring results have
generally indicated that pinnipeds typically move or flush from the
haul-out in response to human presence or visual disturbance, although
some individuals typically remain hauled-out (e.g., SCWA, 2012). The
nature of response is generally dependent on species. For example,
California sea lions and northern elephant seals have been observed as
less sensitive to stimulus than harbor seals during monitoring at
numerous sites. Monitoring of pinniped disturbance as a result of
abalone research in the Channel Islands showed that while harbor seals
flushed at a rate of 69 percent, California sea lions flushed at a rate
of only 21 percent. The rate for elephant seals declined to 0.1 percent
(VanBlaricom, 2010).
Upon the occurrence of low-severity disturbance (i.e., the approach
of a vessel or person as opposed to an explosion or sonic boom),
pinnipeds typically exhibit a continuum of responses, beginning with
alert movements (e.g., raising the head), which may then escalate to
movement away from the stimulus and possible flushing into the water.
Flushed pinnipeds typically re-occupy the haul-out within minutes to
hours of the stimulus.
In a popular tourism area of the Pacific Northwest where human
disturbances occurred frequently, past studies observed stable
populations of seals over a twenty-year period (Calambokidis et al.,
1991). Despite high levels of seasonal disturbance by tourists using
both motorized and non-motorized vessels, Calambokidis et al. (1991)
observed an increase in site use (pup rearing) and classified this area
as one of the most important pupping sites for seals in the region.
Another study observed an increase in seal vigilance when vessels
passed the haul-out site, but then vigilance relaxed within ten minutes
of the vessels' passing (Fox, 2008). If vessels passed frequently
within a short time period (e.g., 24 hours), a reduction in the total
number of seals present was also observed (Fox, 2008).
Level A harassment, serious injury, or mortality could likely only
occur as a result of trampling in a stampede (a potentially dangerous
occurrence in which large numbers of animals succumb to mass panic and
rush away from a stimulus) or abandonment of pups. Pups could be
present at times during AFSC research effort, but AFSC researchers take
precautions to minimize disturbance and prevent any possibility of
stampedes, including choosing travel routes as far away from hauled
pinnipeds as possible and by

[[Page 37667]]

moving sample site locations to avoid consistent haulout areas. In
addition, harbor seal pups are extremely precocious, swimming and
diving immediately after birth and throughout the lactation period,
unlike most other phocids which normally enter the sea only after
weaning (Lawson and Renouf, 1985; Cottrell et al., 2002; Burns et al.,
2005). Lawson and Renouf (1987) investigated harbor seal mother-pup
bonding in response to natural and anthropogenic disturbance. In
summary, they found that the most critical bonding time is within
minutes after birth. As such, it is unlikely that infrequent
disturbance resulting from AFSC research would interrupt the brief
mother-pup bonding period within which disturbance could result in
separation.
Disturbance of pinnipeds caused by AFSC survey activities would be
expected to last for only short periods of time, separated by
significant amounts of time in which no disturbance occurred. Because
such disturbance is sporadic, rather than chronic, and of low
intensity, individual marine mammals are unlikely to incur any
detrimental impacts to vital rates or ability to forage and, thus, loss
of fitness. Correspondingly, even local populations, much less the
overall stocks of animals, are extremely unlikely to accrue any
significantly detrimental impacts.

Anticipated Effects on Marine Mammal Habitat

Effects to Prey--In addition to direct, or operational,
interactions between fishing gear and marine mammals, indirect (i.e.,
biological or ecological) interactions occur as well, in which marine
mammals and fisheries both utilize the same resource, potentially
resulting in competition that may be mutually disadvantageous (e.g.,
Northridge, 1984; Beddington et al., 1985; Wickens, 1995). Marine
mammal prey varies by species, season, and location and, for some, is
not well documented. There is some overlap in prey of marine mammals
and the species sampled and removed during AFSC research surveys, with
primary species of concern being walleye pollock (Gadus chalcogrammus),
Pacific cod (G. macrocephalus), Atka mackerel (Pleurogrammus
monopterygius), sablefish (Anoplopoma fimbria), salmonids (Oncorhynchus
spp.), and small, energy-rich, forage fish species such as Pacific
sandlance (Ammodytes spp.) and Pacific herring (Clupea pallasi).
However, the total amount of these species taken in research
surveys is very small relative to their overall biomass in the area
(See Section 4.3.3 of the AFSC EA for more information on fish catch
during research surveys). For example, AFSC research surveys are
expected to catch approximately 433 metric tons (mt) of pollock per
year in the GOARA. Research catch is therefore negligible compared to
the allowable commercial harvest (111,530 mt in 2014) in the same area.
For most commercial species, the average annual research catch is less
than one percent of the allowable commercial catch. Other species of
fish and invertebrates that are used as prey by marine mammals are
taken in research surveys as well but, as indicated by these examples,
the proportions of research catch compared to biomass and commercial
harvest is very small.
Several AFSC fisheries research projects target prey of endangered
western DPS Steller sea lions within the GOARA and BSAIRA. These
studies are, in part, designed to assess aspects of the seasonal
abundance and distribution of sea lion prey as part of a comprehensive
examination of how nutritional status and prey availability may affect
the recovery of the species. Some of these studies may be conducted
within designated critical habitat for Steller sea lions, no-transit
zones around rookeries, and areas designated as fishery closure zones.
The primary prey caught in critical habitat includes rockfishes,
pollock, Atka mackerel, arrowtooth flounder, and Pacific cod. Table 9-1
of AFSC's application shows the average annual AFSC fisheries research
catch within Steller sea lion critical habitat. As described above,
these amounts of prey are a small fraction of the commercial harvest
total allowable catch, and an even smaller fraction of the biomass
available to Steller sea lions. AFSC fisheries research catches are
therefore anticipated to result in little to no effects on foraging sea
lions in the general area or in their critical habitat. Prior ESA
section 7 consultations conducted as part of the process for obtaining
regional scientific research permits have not found any of the
fisheries research prey removals to jeopardize listed species or to
adversely modify critical habitat.
In addition to the small total biomass taken, some of the size
classes of fish targeted in research surveys are very small (e.g.,
juvenile salmonids are typically only centimeters long), and these
small size classes are not known to be prey of marine mammals. Research
catches are also distributed over a wide area because of the random
sampling design covering large sample areas. Fish removals by research
are therefore highly localized and unlikely to affect the spatial
concentrations and availability of prey for any marine mammal species.
The overall effect of research catches on marine mammals through
competition for prey may therefore be considered insignificant for all
species.
Acoustic Habitat--Acoustic habitat is the soundscape--which
encompasses all of the sound present in a particular location and time,
as a whole--when considered from the perspective of the animals
experiencing it. Animals produce sound for, or listen for sounds
produced by, conspecifics (communication during feeding, mating, and
other social activities), other animals (finding prey or avoiding
predators), and the physical environment (finding suitable habitats,
navigating). Together, sounds made by animals and the geophysical
environment (e.g., produced by earthquakes, lightning, wind, rain,
waves) make up the natural contributions to the total acoustics of a
place. These acoustic conditions, termed acoustic habitat, are one
attribute of an animal's total habitat.
Soundscapes are also defined by, and acoustic habitat influenced
by, the total contribution of anthropogenic sound. This may include
incidental emissions from sources such as vessel traffic, or may be
intentionally introduced to the marine environment for data acquisition
purposes (as in the AFSC's use of active acoustic sources).
Anthropogenic noise varies widely in its frequency content, duration,
and loudness and these characteristics greatly influence the potential
habitat-mediated effects to marine mammals (please also see the
previous discussion on masking in the ``Acoustic Effects'' subsection),
which may range from local effects for brief periods of time to chronic
effects over large areas and for long durations. Depending on the
extent of effects to habitat, animals may alter their communications
signals (thereby potentially expending additional energy) or miss
acoustic cues (either conspecific or adventitious). For more detail on
these concepts see, e.g., Barber et al., 2010; Pijanowski et al., 2011;
Francis and Barber, 2013; Lillis et al., 2014.
Problems arising from a failure to detect cues are more likely to
occur when noise stimuli are chronic and overlap with biologically
relevant cues used for communication, orientation, and predator/prey
detection (Francis and Barber, 2013). As described above (``Acoustic
Effects''), the signals emitted by AFSC active acoustic sources are
generally high frequency, of short

[[Page 37668]]

duration, and transient. These factors mean that the signals will
attenuate rapidly (not travel over great distances), may not be
perceived or affect perception even when animals are in the vicinity,
and would not be considered chronic in any given location. AFSC use of
these sources is widely dispersed in both space and time. In
conjunction with the prior factors, this means that it is highly
unlikely that AFSC use of these sources would, on their own, have any
appreciable effect on acoustic habitat. Sounds emitted by AFSC vessels
would be of lower frequency and continuous, but would also be widely
dispersed in both space and time. AFSC vessel traffic--including both
sound from the vessel itself and from the active acoustic sources--is
of very low density compared to commercial shipping traffic or
commercial fishing vessels and would therefore be expected to represent
an insignificant incremental increase in the total amount of
anthropogenic sound input to the marine environment.
Physical Habitat--AFSC conducts some bottom trawling, which may
physically damage seafloor habitat. Physical damage may include
furrowing and smoothing of the seafloor as well as the displacement of
rocks and boulders, and such damage can increase with multiple contacts
in the same area (Schwinghamer et al., 1998; Kaiser et al., 2002; Malik
and Mayer, 2007; NRC, 2002). The effects of bottom contact gear differ
in each type of benthic environment. In sandy habitats with strong
currents, the furrows created by mobile bottom contact gear quickly
begin to erode because lighter weight sand at the edges of furrows can
be easily moved by water back towards the center of the furrow (NRC,
2002). Duration of effects in these environments therefore tend to be
very short because the terrain and associated organisms are accustomed
to natural disturbance. By contrast, the physical features of more
stable hard bottom habitats are less susceptible to disturbance, but
once damaged or removed by fishing gear, the organisms that grow on
gravel, cobbles, and boulders can take years to recover, especially in
deeper water where there is less natural disturbance (NRC, 2002).
However, the area of benthic habitat affected by AFSC research each
year would be a very small fraction of total area and effects are not
expected to occur in areas of particular importance.
Damage to seafloor habitat may also harm infauna and epifauna
(i.e., animals that live in or on the seafloor or on structures on the
seafloor), including corals (Schwinghamer et al., 1998; Collie et al.,
2000; Stevenson et al., 2004). In general, recovery of biological
damage varies based on the type of fishing gear used, the type of
seafloor surface (i.e., mud, sand, gravel, mixed substrate), and the
level of repeated disturbances, but would be expected to occur within
1-18 months. However, repeated disturbance of an area can prolong the
recovery time (Stevenson et al., 2004), and recovery of corals may take
significantly longer. However, AFSC catch records show that only
minimal amounts of coral are captured (annual average of 100 kg of
coral per year for most species groups). Relatively small areas would
be impacted by AFSC bottom trawling and, because such surveys are
conducted in the same areas but not in the exact same locations, they
are expected to cause single rather than repeated disturbances in any
given area. AFSC activities would not be expected to have any other
impacts on physical habitat.
As described in the preceding, the potential for AFSC research to
affect the availability of prey to marine mammals or to meaningfully
impact the quality of physical or acoustic habitat is considered to be
insignificant for all species. Effects to habitat will not be discussed
further in this document.

Estimated Take

This section provides an estimate of the number of incidental takes
proposed for authorization, which will inform both NMFS's consideration
of whether the number of takes is ``small'' and the negligible impact
determination.
Except with respect to certain activities not pertinent here,
section 3(18) of the MMPA defines ``harassment'' as: any act of
pursuit, torment, or annoyance which (i) has the potential to injure a
marine mammal or marine mammal stock in the wild (Level A harassment);
or (ii) has the potential to disturb a marine mammal or marine mammal
stock in the wild by causing disruption of behavioral patterns,
including, but not limited to, migration, breathing, nursing, breeding,
feeding, or sheltering (Level B harassment).
Take of marine mammals incidental to AFSC research activities could
occur as a result of (1) injury or mortality due to gear interaction
(Level A harassment, serious injury, or mortality); (2) behavioral
disturbance resulting from the use of active acoustic sources (Level B
harassment only); or (3) behavioral disturbance of pinnipeds resulting
from incidental approach of researchers (Level B harassment only).
Below we describe how the potential take is estimated.

Estimated Take Due to Gear Interaction

In order to estimate the number of potential incidents of take that
could occur through gear interaction, we first consider AFSC's and
IPHC's record of past such incidents, and then consider in addition
other species that may have similar vulnerabilities to AFSC trawl and
IPHC longline gear as those species for which we have historical
interaction records. Historical interactions with research gear are
described in Table 4, and we anticipate that all species that
interacted with AFSC or IPHC fisheries research gear historically could
potentially be taken in the future. Available records are for the years
2004 through present (AFSC) and 1998 through present (IPHC). All
historical AFSC interactions have taken place in the GOARA, and have
occurred during use of either the Cantrawl surface trawl net or with a
bottom trawl. Historical IPHC interactions have occurred during use of
bottom longlines and were located in the GOARA (southeast Alaska) or
west coast (offshore Oregon). AFSC has no historical interactions for
any longline or gillnet gear, and there are no historical interactions
in the BSAIRA or CSBSRA. Please see Figures 6-1 and C-6 in the AFSC
request for authorization for specific locations of these incidents.

Table 4--Historical Interactions With Research Gear
--------------------------------------------------------------------------------------------------------------------------------------------------------
Number
Gear Survey Date Location \1\ Species Number released Total
killed alive
--------------------------------------------------------------------------------------------------------------------------------------------------------
Bottom longline................... IPHC setline........ 7/17/1999 West coast............. Harbor seal......... 1 ......... 1
Bottom longline................... IPHC setline........ 7/23/2003 SE Alaska.............. Steller sea lion.... 1 ......... 1
Bottom longline................... IPHC setline........ 7/16/2007 SE Alaska.............. Steller sea lion.... 1 ......... 1

[[Page 37669]]

Bottom trawl...................... Gulf of Alaska 6/13/2009 GOARA.................. Northern fur seal 1 ......... 1
Biennial Shelf and \2\.
Slope Bottom Trawl
Groundfish Survey.
Bottom longline................... IPHC setline........ 7/31/2011 West coast............. Harbor seal......... 1 ......... 1
Surface trawl (Cantrawl).......... Gulf of Alaska 9/10/2011 GOARA.................. Dall's porpoise..... 1 ......... 1
Assessment.
Surface trawl (Cantrawl).......... Gulf of Alaska 9/21/2011 GOARA.................. Dall's porpoise..... 1 ......... 1
Assessment.
Bottom trawl...................... ADFG Large Mesh 9/5/2014 GOARA.................. Harbor seal......... 1 ......... 1
Trawl Survey.
Bottom longline................... IPHC setline........ 7/22/2016 SE Alaska.............. Steller sea lion.... 1 ......... 1
Total individuals captured.... .................... .............. ....................... Northern fur seal... 1 ......... 1
.................... .............. ....................... Dall's porpoise..... 2 ......... 2
.................... .............. ....................... Harbor seal......... 3 ......... 3
.................... .............. ....................... Steller sea lion.... 3 ......... 3
--------------------------------------------------------------------------------------------------------------------------------------------------------
\1\ AFSC interactions are described by research area. IPHC research programs are not distributed according to AFSC research areas and so are described
by geographic location. Specific locations of all interactions are shown in Figures 6-1 and C-6 of the application.
\2\ Based on the location of this incident, the captured animal was believed to be from the eastern Pacific stock of northern fur seal.

In order to use these historical interaction records as the basis
for the take estimation process, and because we have no specific
information to indicate whether any given future interaction might
result in M/SI versus Level A harassment, we conservatively assume that
all interactions equate to mortality for these fishing gear
interactions. AFSC and IPHC have historically had only infrequent
interactions with marine mammals, e.g., from 2004-2015 AFSC conducted
at least 1,250 trawl tows per year, with only three (a fourth occurred
during a survey conducted by the Alaska Department of Fish and Game)
marine mammal interactions (Table 4). However, we assume that any of
the historically-captured species (northern fur seal, Dall's porpoise,
harbor seal, Steller sea lion) could be captured in any year.
We consider all of the interaction records available to us. In
consideration of these data, we assume that one individual of each of
the historically-captured species (Table 4) could be captured per year
over the course of the five-year period of validity for these proposed
regulations, specific to relevant survey operations where the species
occur (e.g., one harbor seal taken per year specific to IPHC longline
survey operations, one Dall's porpoise taken per year specific to AFSC
trawl survey operations in GOARA, one Dall's porpoise taken per year
specific to AFSC trawl survey operations in BSAIRA). Table 5 shows the
projected five-year total captures of the historically-captured species
for this proposed rule, as described above, for AFSC trawl gear and
IPHC longline gear only. Although more than one individual Dall's
porpoise has been captured in a single year, interactions have
historically occurred only infrequently. Therefore, we believe that the
above assumption appropriately reflects the likely total number of
individuals involved in research gear interactions over a five-year
period and that the assumption is precautionary in that it separately
accounts for potential vulnerability of species to gear interaction in
the different research areas. Harbor seals are expected to have less
frequency of interaction than the fur seal or Steller sea lion due to
its more inshore and coastal distribution. AFSC requests authorization
of one take per harbor seal stock in each relevant research area over
the 5-year period (note that these takes are not included in Table 5
but are incorporated in Table 7). These estimates are based on the
assumption that annual effort (e.g., total annual trawl tow time) over
the proposed five-year authorization period will be approximately
equivalent to the annual effort during prior years for which we have
interaction records.

Table 5--Projected Five-Year Total Take for Historically Captured Species \1\
--------------------------------------------------------------------------------------------------------------------------------------------------------
AFSC GOARA average AFSC BSAIRA IPHC average
Gear Species annual take average annual annual take Projected 5-year
(total) take (total) (total) \2\ total
--------------------------------------------------------------------------------------------------------------------------------------------------------
Trawl..................................... Northern fur seal \3\....... 1 (5) 1 (5) .................. 10
Dall's porpoise............. 1 (5) 1 (5) .................. 10
Longline.................................. Harbor seal................. .................. .................. 1 (5) 5
Steller sea lion............ .................. .................. 1 (5) 5
--------------------------------------------------------------------------------------------------------------------------------------------------------
\1\ Projected takes based on species interaction records in analogous commercial fisheries (versus historical records) are incorporated in Table 7
below, as are all projected takes within the CSBSRA.
\2\ IPHC activities are not defined by the three AFSC research areas and may occur anywhere within the IPHC research areas off the U.S. west coast or in
the Gulf of Alaska and Bering Sea. Projected IPHC harbor seal takes could occur to any stock of harbor seal. Historical IPHC takes of Steller sea lion
have been of the eastern DPS (based on geographic location), but potential future takes could occur to either eastern or western DPS.
\3\ Referring to expected potential future takes of eastern Pacific stock northern fur seals in AFSC trawl gear on basis of historical record.
Additional take of California stock northern fur seals, inferred based on vulnerability and geographic overlap, are incorporated in Table 7 below.

[[Page 37670]]

As background to the process of determining which species not
historically taken may have sufficient vulnerability to capture in AFSC
gear to justify inclusion in the take authorization request (or whether
species historically taken may have vulnerability to gears in which
they have not historically been taken or additional vulnerability not
reflected above due to activity in other areas such as the CSBSRA), we
note that the AFSC is NMFS' research arm in Alaska and may be
considered as a leading source of expert knowledge regarding marine
mammals (e.g., behavior, abundance, density) in the areas where they
operate. The species for which the take request was formulated were
selected by the AFSC, and we have concurred with these decisions. We
also note that, in addition to consulting NMFS's List of Fisheries
(LOF; described below), the historical interaction records described
above for the IPHC informed our consideration of risk of interaction
due to AFSC's use of longline gear (for which there are no historical
interaction records).
In order to estimate the total potential number of incidents of
takes that could occur incidental to the AFSC's use of trawl, longline,
and gillnet gear, and IPHC's use of longline gear, over the five-year
period of validity for these proposed regulations (i.e., takes
additional to those described in Table 5), we first consider whether
there are additional species that may have similar vulnerability to
capture in trawl or longline gear as the five species described above
that have been taken historically and then evaluate the potential
vulnerability of these and other species to additional gears.
We believe that the Pacific white-sided dolphin likely has similar
vulnerability to capture in trawl gear as the Dall's porpoise, given
similar habitat preferences and with documented vulnerability to
capture in both commercial and research trawls. The harbor porpoise is
also considered vulnerable to capture in trawl gear, but likely with
less frequency of interaction given its inshore and coastal
distribution. The Steller sea lion is considered to have similar
vulnerability to capture in trawl gear as the northern fur seal, given
similar habitat preferences and with documented vulnerability to
capture in commercial trawls. In addition to the one northern fur seal
per year from the eastern Pacific stock that could be captured in each
relevant research area (Table 5), we assume that one additional
northern fur seal from the California stock could be taken in trawl
gear over the 5-year period. The assumed lesser frequency of
interaction is due to presumed lower occurrence of California stock fur
seals in AFSC research areas. Only approximately half of this
relatively small stock of fur seals ranges to the eastern GOARA.
Similar to the harbor porpoise, spotted seals are expected to have
similar vulnerability to capture in trawl gear as historically captured
pinnipeds, but with less frequency of interaction due to its more
inshore and coastal distribution. AFSC requests authorization of one
take of spotted seal in each relevant research area over the 5-year
period. This assumption is supported by LOF records (Table 7).
Historical IPHC take records also illustrate likely similar
vulnerabilities to capture by AFSC longline gear. However, due to
reduced use of longline gear by AFSC relative to IPHC activity, expects
that one Steller sea lion from each DPS could be taken over the 5-year
period in each relevant research area. Despite IPHC records of harbor
seal capture in longline gear, we do not believe that AFSC use of
longline gear presents similar risk, in part due to the relative
infrequency of use but also because of a lack of expected geographic
overlap between AFSC longline sets and harbor seal occurrence. IPHC
conducts many more longline sets per year but also conducts survey
effort further inshore than does IPHC (water depths of 18 m). No take
of harbor seals incidental to AFSC longline survey effort is proposed.
Northern fur seals and California sea lions are considered analogous to
Steller sea lions due to similar vulnerability to capture in longline
gear. AFSC has requested authorization of one take over the 5-year
period for each fur seal stock in each research area where fur seals
are found and, on behalf of IPHC, requests authorization of one fur
seal per year (which could be from either stock) and one California sea
lion over the 5-year period. Finally, the spotted seal may have similar
vulnerability to interaction with longline gear as the harbor seal, but
likely with less frequency given the limited overlap between the
species range and survey effort. We propose to authorize one take over
the 5-year period for IPHC survey effort, but none for AFSC given very
little expected overlap. These assumptions are supported by LOF records
(Table 7).
In order to evaluate the potential vulnerability of additional
species to trawl and longline and of all species to gillnet gear, we
first consulted the LOF, which classifies U.S. commercial fisheries
into one of three categories according to the level of incidental
marine mammal M/SI that is known to occur on an annual basis over the
most recent five-year period (generally) for which data has been
analyzed: Category I, frequent incidental M/SI; Category II, occasional
incidental M/SI; and Category III, remote likelihood of or no known
incidental M/SI. We provide summary information, as presented in the
2017 LOF (82 FR 3655; January 12, 2017), in Table 6. In order to
simplify information presented, and to encompass information related to
other similar species from different locations, we group marine mammals
by genus (where there is more than one member of the genus found in
U.S. waters). Where there are documented incidents of M/SI incidental
to relevant commercial fisheries, we note whether we believe those
incidents provide sufficient basis upon which to infer vulnerability to
capture in AFSC or IPHC research gear. For a listing of all Category I,
II, and II fisheries using relevant gears, associated estimates of
fishery participants, and specific locations and fisheries associated
with the historical fisheries takes indicated in Table 6 below, please
see the 2017 LOF. For specific numbers of marine mammal takes
associated with these fisheries, please see the relevant SARs. More
information is available online at www.nmfs.noaa.gov/pr/interactions/fisheries/lof.html and www.nmfs.noaa.gov/pr/sars/.

Table 6--U.S. Commercial Fisheries Interactions for Trawl, Longline, and Gillnet Gear for Relevant Species
--------------------------------------------------------------------------------------------------------------------------------------------------------
Vulnerability Vulnerability Vulnerability
Species \1\ Trawl \2\ inferred? Longline \2\ inferred? Gillnet \2\ inferred?
--------------------------------------------------------------------------------------------------------------------------------------------------------
North Pacific right whale......................... N N N N N N
Bowhead whale..................................... N N N N N N
Gray whale........................................ Y N N N Y N
Humpback whale.................................... Y N Y N Y N

[[Page 37671]]

Balaenoptera spp.................................. Y N Y N Y N
Sperm whale....................................... N N Y Y N N
Kogia spp......................................... n/a n/a Y N n/a n/a
Cuvier's beaked whale............................. N N Y N N N
Baird's beaked whale.............................. N N N N N N
Mesoplodon spp.................................... N N Y N N N
Beluga whale...................................... N Y N N Y N
Common bottlenose dolphin......................... n/a n/a Y Y n/a n/a
Stenella spp...................................... n/a n/a Y N n/a n/a
Delphinus spp..................................... n/a n/a Y Y n/a n/a
Lagenorhynchus spp................................ Y Y N N Y Y
Northern right whale dolphin...................... n/a n/a N N n/a n/a
Risso's dolphin................................... n/a n/a Y Y n/a n/a
Killer whale...................................... Y N Y Y N N
Globicephala spp.................................. n/a n/a Y Y n/a n/a
Harbor porpoise................................... Y Y Y N Y Y
Dall's porpoise \3\............................... n/a n/a Y Y Y Y
Guadalupe fur seal \4\............................ n/a n/a N N n/a n/a
Northern fur seal \3\............................. n/a n/a Y Y Y Y
California sea lion \5\........................... n/a n/a Y Y n/a n/a
Steller sea lion \3\.............................. Y Y n/a n/a Y Y
Bearded seal...................................... Y Y N N N N
Phoca spp \3\..................................... Y Y n/a n/a Y Y
Ringed seal....................................... Y Y Y Y N N
Ribbon seal....................................... Y Y N N N N
Northern elephant seal............................ Y Y Y N Y N
--------------------------------------------------------------------------------------------------------------------------------------------------------
\1\ Please refer to Table 3 for taxonomic reference.
\2\ Indicates whether any member of the genus has documented incidental M/SI in a U.S. fishery using that gear in the most recent five-year timespan for
which data is available. For those species not expected to occur in Alaskan waters, trawl and gillnet gear are not applicable (these gears would only
be used in Alaskan waters).
\3\ This exercise is considered ``not applicable'' for those species historically captured by AFSC or IPHC gear. Historical record, rather than analogy,
is considered the best information upon which to base a take estimate.
\4\ It is likely that Guadalupe fur seals are taken in Mexican fisheries, but there are no records available to us.
\5\ There are no records of take for California sea lions in commercial longline fisheries, but there have been multiple takes of California sea lions
in longline surveys conducted by NMFS's Southwest Fisheries Science Center. We therefore infer vulnerability for the species to research longline
gear.

Information related to incidental M/SI in relevant commercial
fisheries is not, however, the sole determinant of whether it may be
appropriate to authorize take incidental to AFSC survey operations. A
number of factors (e.g., species-specific knowledge regarding animal
behavior, overall abundance in the geographic region, density relative
to AFSC survey effort, feeding ecology, propensity to travel in groups
commonly associated with other species historically taken) were taken
into account by the AFSC to determine whether a species may have a
similar vulnerability to certain types of gear as historically taken
species. In some cases, we have determined that species without
documented M/SI may nevertheless be vulnerable to capture in AFSC
research gear. Similarly, we have determined that some species groups
with documented M/SI are not likely to be vulnerable to capture in AFSC
gear. In these instances, we provide further explanation below. Those
species with no records of historical interaction with AFSC research
gear and no documented M/SI in relevant commercial fisheries, and for
which the AFSC has not requested the authorization of incidental take,
are not considered further in this section. The AFSC believes generally
that any sex or age class of those species for which take authorization
is requested could be captured.
In order to estimate a number of individuals that could potentially
be captured in AFSC research gear for those species not historically
captured, we first determine which species may have vulnerability to
capture in a given gear. Of those species, we then determine whether
any may have similar propensity to capture in a given gear as a
historically captured species. For these species, we assume it is
possible that take could occur while at the same time contending that,
absent significant range shifts or changes in habitat usage, capture of
a species not historically captured would likely be a very rare event.
Therefore, we assume that capture would be a rare event such that
authorization of a single take over the five-year period, for each
region where the gear is used and the species is present, is likely
sufficient to capture the risk of interaction.
Trawl--From the 2017 LOF, we infer vulnerability to trawl gear for
the bearded seal, ringed seal, ribbon seal, and northern elephant seal.
This is in addition to the species for which vulnerability is indicated
by historical AFSC interactions (described above).
For the beluga whale, we believe that there is a reasonable
likelihood of incidental take in trawl gear although there are no
records of incidental M/SI in relevant commercial fisheries. Commercial
fisheries using trawl gear have largely been absent from areas where
beluga whales occur and, in particular, there are no commercial trawl
fisheries in the CSBSRA. AFSC examined the potential for incidental
take of beluga whales by evaluating the areas of overlap between the
proposed fisheries research activities and beluga whale distribution,
considering the seasonality of both the research activities and the
species distributions as well as other factors that may influence the
degree of potential overlap

[[Page 37672]]

such as sea and shorefast ice occurrence. In considering the possible
take of beluga whales, the AFSC considered that beluga whales show
behavior similar to large dolphins and porpoises. While no belugas have
been taken in AFSC research or commercial trawl fisheries, there have
been takes of large dolphins elsewhere in trawls. Beluga whales may
occur in summer periods within the Chukchi and Beaufort Sea regions
where the AFSC may be conducting trawl surveys. Thus, AFSC has
requested authorization of one take each from two stocks of beluga
whale (eastern Chukchi stock and Beaufort Sea stock) in fisheries
research trawl surveys over the 5-year authorization period. Potential
spatiotemporal overlap between AFSC trawl survey activities and other
beluga whale stocks was evaluated and determined to not support a take
authorization request for other stocks of beluga whale.
It is also possible that a captured animal may not be able to be
identified to species with certainty. Certain pinnipeds and small
cetaceans are difficult to differentiate at sea, especially in low-
light situations or when a quick release is necessary. For example, a
captured delphinid that is struggling in the net may escape or be freed
before positive identification is made. Therefore, the AFSC has
requested the authorization of incidental take for one unidentified
pinniped and one unidentified small cetacean in trawl gear for each
research area over the course of the five-year period of proposed
authorization. One exception is for small cetaceans in the CSBSRA, as
no cetacean interactions with trawl gear are expected in that region
(other than the aforementioned potential beluga whale interactions), as
small cetaceans occur only rarely in this region.
Longline--The process is the same as is described above for trawl
gear. From the 2017 LOF, we infer vulnerability to longline gear for
the Dall's porpoise, Risso's dolphin, bottlenose dolphin, common
dolphin, short-finned pilot whale, and ringed seal. This is in addition
to the species for which vulnerability is indicated by historical AFSC
interactions (described above).
Based on the 2017 LOF and historical observations of sperm whale
and killer whale interactions with research longline gear, we also
infer vulnerability to interaction with longline gear for killer whales
(Alaska resident stock only) and sperm whales (North Pacific stock
only). Although we generally believe that, despite records of
interaction with analogous commercial fisheries, the potential for
incidental take of any large whale (i.e., baleen whales or sperm
whale), beaked whale, or killer whale in research gear is so unlikely
as to be discountable, there is a long history of attempted depredation
of longline gear by animals from these stocks in Alaska, with take of
these species having occurred in commercial fisheries. Between 2010 and
2014, five sperm whales are recorded as having been seriously injured
in the Gulf of Alaska sablefish longline fishery, while there have been
two instances of killer whale M/SI in BSAI longline fisheries (Helker
et al., 2016). Cetaceans have never been caught or entangled in AFSC or
IPHC longline research gear. If interactions occur, marine mammals
depredate hooked fish from the gear, but typically leave the hooks
attached although occasionally bent or broken (i.e., evidence of the
interaction). Certain species, particularly killer whales in the Bering
Sea and sperm whales in the Gulf of Alaska, are commonly attracted to
longline fishing operations and are adept at removing fish from
longline gear as it is retrieved. Although we consider it unlikely that
AFSC or IPHC research activities would result in any takes of either
sperm whales or killer whales, AFSC has requested the authorization of
such take as a precautionary measure, given the observed interactions
of these species with research longline gear. Since longline
depredation by sperm whales is known to occur only in Alaskan waters,
requested take is limited to the North Pacific stock. Commercial
fishery takes have been reported for both transient and resident stocks
of killer whale. However, the Alaska resident stock consumes fish
(e.g., Herman et al., 2005) and is most likely to be involved in
depredation of research catch. In contrast, transient killer whales
feed on marine mammals and are less likely to interact with research
longline gears, and the limited effort for AFSC and IPHC research
surveys compared to commercial fisheries does not justify take
authorization for transient whales.
Although there are LOF interaction records in longlines for
stenellid dolphin species, the harbor porpoise, and the northern
elephant seal, we do not propose to authorize take of these species
through use of longline. No take is anticipated for the striped dolphin
or for the long-beaked stock of common dolphin and coastal stock of
bottlenose dolphin because of their expected pelagic and southerly
distributions (respectively) relative to expected IPHC survey effort.
Harbor porpoise have only been recorded as taken in commercial
fisheries through use of pelagic longline in the Atlantic Ocean; there
are no records of incidental take of harbor porpoise in longline
fisheries in Alaska or off the U.S. west coast. Similarly, the LOF
indicates that elephant seal interaction occurred only in a Hawaiian
pelagic longline fishery.
As described for trawl gear, it is also possible that a captured
animal may not be able to be identified to species with certainty.
Although we expect that cetaceans would likely be able to be identified
when captured in longline gear, pinnipeds are considered more likely to
escape before the animal may be identified. Therefore, the AFSC has
requested the authorization of incidental take for one unidentified
pinniped for each relevant research area, in addition to one
unidentified pinniped captured in IPHC surveys, over the course of the
five-year period of proposed authorization.
Gillnet--The process is the same as is described above for trawl
gear. From the 2017 LOF, we infer vulnerability to gillnet gear for the
Pacific white-sided dolphin, harbor porpoise, Dall's porpoise, harbor
seal, northern fur seal, and Steller sea lion. Gillnets are used only
in Prince William Sound and at Little Port Walter in southeast Alaska.
Therefore, only one take is proposed for authorization for relevant
stocks of the vulnerable species over the 5-year period. This includes
both the eastern Pacific and California stocks of northern fur seal and
the Prince William Sound and Sitka/Chatham Strait stocks of harbor
seal. Although there are LOF interaction records in gillnets for the
beluga whale and the northern elephant seal, we do not expect these
species to be present in areas where AFSC proposes to use gillnet
research gear and no take of these species through use of gillnet is
proposed for authorization.
AFSC also expects that there may be an interaction resulting in
escape of an unidentified cetacean in gillnet gear, and has requested
the authorization of incidental take for one unidentified cetacean over
the course of the five-year period of proposed authorization.

[[Page 37673]]

Table 7--Total Estimated Take Due to Gear Interaction, 2018-23 \1\
--------------------------------------------------------------------------------------------------------------------------------------------------------
Estimated 5-year
Species Estimated 5-year total, Estimated 5-year total, total, longline Estimated 5-year Total, all gears
trawl longline (AFSC) (IPHC) \2\ total, gillnet
--------------------------------------------------------------------------------------------------------------------------------------------------------
Sperm whale (North Pacific)..... ............................ 1 (GOARA)................... 1 .................. 2
Beluga whale (eastern Chukchi).. 1 (CSBSRA).................. ............................ .................. .................. 1
Beluga whale (Beaufort Sea)..... 1 (CSBSRA).................. ............................ .................. .................. 1
Bottlenose dolphin (offshore)... ............................ ............................ 1 .................. 1
Common dolphin.................. ............................ ............................ 1 .................. 1
Pacific white-sided dolphin..... 5 (GOARA)................... ............................ .................. 1 6
Risso's dolphin................. ............................ ............................ 1 .................. 1
Killer whale (Alaska resident).. ............................ 1 (BSAIRA).................. 1 .................. 2
Short-finned pilot whale........ ............................ ............................ 1 .................. 1
Harbor porpoise (Southeast ............................ ............................ .................. .................. 1
Alaska) \3\.
Harbor porpoise (Gulf of Alaska) 1........................... ............................ .................. 1 2
Harbor porpoise (Bering Sea).... 1........................... ............................ .................. .................. 1
Dall's porpoise................. 10 (5 GOARA/5 BSAIRA)....... 2 (1 GOARA/1 BSAIRA)........ 1 1 14
Northern fur seal (eastern 10 (5 GOARA/5 BSAIRA)....... 2 (1 GOARA/1 BSAIRA)........ 5 1 13-18
Pacific).
Northern fur seal (California).. 1 (GOARA)................... 1 (GOARA)................... .................. 1 3-8
California sea lion............. ............................ ............................ 1 .................. 1
Steller sea lion (eastern)...... 5........................... 1........................... 5 1 7-12
Steller sea lion (western)...... 10 (5 GOARA/5 BSAIRA)....... 2 (1 GOARA/1 BSAIRA)........ .................. 1 13-18
Bearded seal.................... 2 (1 BSAIRA/1 CSBSRA)....... ............................ .................. .................. 2
Harbor seal \4\................. 12.......................... ............................ 5 2 19
Spotted seal.................... 2 (1 BSAIRA/1 CSBSRA)....... ............................ 1 .................. 3
Ringed seal..................... 2 (1 BSAIRA/1 CSBSRA)....... 1........................... 1 .................. 4
Ribbon seal..................... 2 (1 BSAIRA/1 CSBSRA)....... ............................ .................. .................. 2
Northern elephant seal.......... 1........................... ............................ .................. .................. 1
Unidentified pinniped \5\....... 3........................... 2........................... 1 .................. 6
Unidentified small cetacean \6\. 2........................... ............................ .................. 1 3
--------------------------------------------------------------------------------------------------------------------------------------------------------
\1\ Please see Table 6 and preceding text for derivation of take estimates. Takes proposed for authorization are informed by area- and gear-specific
vulnerability. However, IPHC longline takes are considered separately. AFSC use of gillnets occurs only in the GOARA. Only trawl gear is used in the
CSBSRA.
\2\ Potential IPHC takes are not specific to any area or stock. For example, the one expected take of Dall's porpoise could occur to an individual of
either the CA/OR/WA or Alaska stocks. For harbor seals, although five total takes may occur over the 5-year period of the proposed regulations, no
more than one take is anticipated from any given stock.
\3\ For harbor porpoise in southeast Alaska, we propose to authorize take of one animal in all gears combined (i.e., trawl and gillnet) over the 5-year
period. In general, harbor porpoise would be expected to have the same vulnerability to particular gears regardless of stock. However, AFSC proposes
to use acoustic pingers on surface trawl nets in southeast Alaska, reducing the likelihood of porpoise interaction with that gear. Use of acoustic
pingers is proposed for gillnets in both southeast Alaska and in the Gulf of Alaska.
\4\ For trawl gear, the numbers include one take during the 5-year period for each Alaskan harbor seal stock (three stocks in BSAIRA and nine stocks in
GOARA). For gillnet gear, the numbers include one take during the 5-year period for the Prince William Sound and Sitka/Chatham Strait stocks. For IPHC
longline surveys, the five takes proposed for authorization could occur for any harbor seal stock, though no more than one take would be expected to
occur over the 5-year period for any given stock.
\5\ Includes one unidentified pinniped in each research area (trawl) and one unidentified pinniped in the GOARA and BSAIRA and for IPHC surveys
(longline).
\6\ Includes one unidentified small cetacean in the GOARA and BSAIRA (trawl) and one unidentified cetacean in the GOARA (gillnet). This is not
anticipated to apply to harbor porpoise in southeast Alaska, as the already low probability of gear interaction is further reduced through use of
additional mitigation (described in footnote 3).

Whales--For large whales (baleen whales and sperm whales) and small
whales (considered here to be beaked whales, Kogia spp., and killer
whales), observed M/SI is extremely rare for trawl and gillnet gear
and, for most of these species, only slightly more common in longline
gear. Furthermore, with the exception of sperm whales and killer whales
(who attempt to depredate longline gear), most of these species
longline interactions are with pelagic gear. Baleen whale interactions
with longline gear represent entanglements in pelagic mainlines, while
beaked whales and Kogia spp. typically have a pelagic distribution
resulting in a lack of spatial overlap with bottom longline fisheries.
Although whale species could become captured or entangled in AFSC gear,
the probability of interaction is extremely low considering the lower
level of effort relative to that of commercial fisheries. For example,
there were estimated to be three total incidents of sperm whale M/SI in
the Hawaii deep-set longline fishery over a five-year period. This
fishery has 129 participants, and the fishery as a whole exerts
substantially greater effort in a given year than does the AFSC. In a
very rough estimate, we can say that these three estimated incidents
represent an insignificant per-participant interaction rate of 0.005
per year, despite the greater effort. Similarly, there were zero
documented interactions over a five-year period in the Atlantic Ocean,
Caribbean, Gulf of Mexico large pelagics longline fishery, despite a
reported fishing effort of 8,044 sets and 5,955,800 hooks in 2011 alone
(Garrison and Stokes, 2012). With an

[[Page 37674]]

average soak time of ten to fourteen hours, this represents an
approximate minimum of almost sixty million hook hours. AFSC and IPHC
effort would be a small fraction of this per year. Other large whales
and small whales have similarly low rates of interaction with
commercial fisheries, despite the significantly greater effort. In
addition, most large whales and small whales generally have, with few
exceptions, very low densities in areas where AFSC and IPHC research
occurs relative to other species (see Tables 10-12). With exceptions
for sperm whales and killer whales that are known to depredate research
longline gear in particular locations, we believe it extremely unlikely
that any large whale or small whale would be captured or entangled in
AFSC research gear.

Estimated Take Due to Acoustic Harassment

As described previously (``Potential Effects of the Specified
Activity on Marine Mammals and Their Habitat''), we believe that AFSC
use of active acoustic sources has, at most, the potential to cause
Level B harassment of marine mammals. In order to attempt to quantify
the potential for Level B harassment to occur, NMFS (including the AFSC
and acoustics experts from other parts of NMFS) developed an analytical
framework considering characteristics of the active acoustic systems
described previously under ``Description of Active Acoustic Sound
Sources,'' their expected patterns of use, and characteristics of the
marine mammal species that may interact with them. We believe that this
quantitative assessment benefits from its simplicity and consistency
with current NMFS acoustic guidance regarding Level B harassment but
caution that, based on a number of deliberately precautionary
assumptions, the resulting take estimates may be seen as an
overestimate of the potential for behavioral harassment to occur as a
result of the operation of these systems. Additional details on the
approach used and the assumptions made that result in these estimates
are described below.
In 2016, NMFS released updated ``Technical Guidance for Assessing
the Effects of Anthropogenic Sound on Marine Mammal Hearing'' with
revised metrics and thresholds to assess the potential for injury
(e.g., permanent threshold shift) from acoustic sources. While the
AFSC's documents refer to NMFS's historic guidelines, as the acoustic
analysis was completed prior to the release of the technical guidance,
the conclusions regarding the potential for injury remain the same.
Most importantly, the technical guidance now explicitly takes into
account the duration of the sound through the use of the sound exposure
level (SEL) metric, as opposed to the previous use of root mean square
(rms) sound pressure level (SPL). The effect of this different metric,
in particular for the very short duration sounds used for these
echosounders, is to largely reduce the exposure level of sound an
animal is exposed to for short duration sounds (e.g., for a 1 ms ping,
an SPL source level is reduced by 30 dB in the SEL metric) offsetting
changes in the thresholds themselves. While energy is accumulated over
time using SEL, the previous conclusion that an individual would have
to remain exceptionally close to a sound source for unrealistic lengths
of time holds, suggesting the likelihood of injury occurring is
exceedingly small and is therefore not considered further in this
analysis.
The assessment paradigm for active acoustic sources used in AFSC
fisheries research is relatively straightforward and has a number of
key simplifying assumptions. NMFS's current acoustic guidance requires
in most cases that we assume Level B harassment occurs when a marine
mammal receives an acoustic signal at or above a simple step-function
threshold. Sound produced by these sources are very short in duration
(typically on the order of milliseconds), intermittent, have high rise
times, and are operated from moving platforms. They are consequently
considered most similar to impulsive sources, which are subject to the
160 dB rms criterion. Estimating the number of exposures at the
specified received level requires several determinations, each of which
is described sequentially below:
(1) A detailed characterization of the acoustic characteristics of
the effective sound source or sources in operation;
(2) The operational areas exposed to levels at or above those
associated with Level B harassment when these sources are in operation;
(3) A method for quantifying the resulting sound fields around
these sources; and
(4) An estimate of the average density for marine mammal species in
each area of operation.
Quantifying the spatial and temporal dimension of the sound
exposure footprint (or ``swath width'') of the active acoustic devices
in operation on moving vessels and their relationship to the average
density of marine mammals enables a quantitative estimate of the number
of individuals for which sound levels exceed the relevant threshold for
each area. The number of potential incidents of Level B harassment is
ultimately estimated as the product of the volume of water ensonified
at 160 dB rms or higher (to a maximum depth of 500 m) and the
volumetric density of animals determined from simple assumptions about
their vertical stratification in the water column. Specifically,
reasonable assumptions based on what is known about diving behavior
across different marine mammal species were made to segregate those
that predominately remain in the upper 200 m of the water column versus
those that regularly dive deeper during foraging and transit. Because
depths range dramatically along the margin of the continental slope
that define the outer edge of the survey areas, but deeper surveyed
depths rarely range over 500 m in practice, the depth range for
determining volumes was set at 500 m for deep diving species. Methods
for estimating each of these calculations are described in greater
detail in the following sections, along with the simplifying
assumptions made, and followed by the take estimates. Note that the
IPHC does not use active acoustic systems for data acquisition
purposes; therefore, potential Level B harassment is only considered
for AFSC survey operations in the GOARA, BSAIRA, and CSBSRA.
Sound Source Characteristics--An initial characterization of the
general source parameters for the primary active acoustic sources
operated by the AFSC was conducted, enabling a full assessment of all
sound sources used by the AFSC and delineation of Category 1 and
Category 2 sources, the latter of which were carried forward for
analysis here (see Table 2). This auditing of the active acoustic
sources also enabled a determination of the predominant sources that,
when operated, would have sound footprints exceeding those from any
other simultaneously used sources. These sources were effectively those
used directly in acoustic propagation modeling to estimate the zones
within which the 160 dB rms received level would occur.
Many of these sources can be operated in different modes and with
different output parameters. In modeling their potential impact areas,
those features among those given previously in Table 2 (e.g., lowest
operating frequency) that would lead to the most precautionary estimate
of maximum received level ranges (i.e., largest ensonified area) were
used. The effective beam patterns took into account the normal modes in
which these sources are typically operated. While these signals are
brief and intermittent, a conservative assumption was taken in ignoring
the temporal

[[Page 37675]]

pattern of transmitted pulses in calculating Level B harassment events.
Operating characteristics of each of the predominant sound sources were
used in the calculation of effective line-kilometers and area of
exposure for each source in each survey.
Note that, for purposes of this analysis, the EK60 is assumed to
operate at 18 kHz, the ES60 is assumed to operate at 38 kHz, and the
7111 is assumed to operate at 100 kHz. Therefore, we assume that Level
B harassment of low-frequency cetaceans may only occur in response to
exposure to signals from the EK60, as signals from the other two
systems are outside the generalized hearing range for this group.
Similarly, we assume that pinnipeds would not experience harassment
upon exposure to signals from the 7111, which produces signals outside
the generalized hearing range of both otariid and phocid pinnipeds.

Table 8--Effective Exposure Areas for Predominant Acoustic Sources
Across Two Depth Strata
------------------------------------------------------------------------
Effective Effective
exposure area: exposure area:
Active acoustic system Sea surface to Sea surface to
200 m depth 500 m depth
(km\2\) (km\2\)
------------------------------------------------------------------------
Simrad EK60/ME70 narrow beam echosounder 0.0173 0.056
Simrad ES60 multibeam echosounder....... 0.0112 0.036
Reson 7111 multibeam echosounder........ 0.1419 0.914
------------------------------------------------------------------------

Among Category 2 sources (Table 2), three predominant sources
(Table 8) were identified as having the largest potential impact zones
during operations, based on their relatively lower output frequency,
higher output power, and their operational pattern of use. Estimated
effective cross-sectional areas of exposure were estimated for each of
the predominant sources using a commercial software package (MATLAB)
and key input parameters including source-specific operational
characteristics (e.g., frequency, beamwidth, source level; see Table 2)
and environmental characteristics (i.e., temperature, salinity, pH, and
latitude). Where relevant, calculations were performed for different
notional operational scenarios and the largest cross-sectional area
used in estimating take (e.g., see Figure 6-2 of AFSC's application,
which displays a simple visualization of a two-dimensional slice of
modeled sound propagation to illustrate the predicted area ensonified
to the 160-dB threshold by the nominal EK60 beam pattern assuming side
lobes of ensonification).
In determining the effective line-kilometers for each of these
predominant sources, the operational patterns of use relative to one
another were further applied to determine which source was the
predominant one operating at any point in time for each survey. When
multiple sound sources are used simultaneously, the one with the
largest potential impact zone in each relevant depth strata is
considered for use in estimating exposures. For example, when species
(e.g., sperm whales) regularly dive deeper than 200 m, the largest
potential impact zone was calculated for both depth strata and in some
cases resulted in a different source being predominant in one depth
stratum or the other. This enabled a more comprehensive way of
accounting for maximum exposures for animals diving in a complex sound
field resulting from simultaneous sources with different spatial
profiles. This overall process effectively resulted in three sound
sources (Table 8; ES60, EK60/ME70, and 7111) comprising the total
effective line-kilometers, their relative proportions depending on the
nature of each survey.
Calculating Effective Line-Kilometers--As described below, based on
the operating parameters for each source type, an estimated volume of
water ensonified at or above the 160 dB rms threshold was determined.
In all cases where multiple sources are operated simultaneously, the
one with the largest estimated acoustic footprint was considered to be
the effective source. This was calculated for each depth stratum, which
in some cases resulted in different sources being predominant in each
depth stratum for all line-kilometers when multiple sources were in
operation; this was accounted for in estimating overall exposures for
species that utilize both depth strata (deep divers). The total number
of line-kilometers associated with relevant surveys was determined, as
was the relative percentage of surveyed linear kilometers associated
with each depth stratum (equating to the proportion of each survey
occurring on the shallower upper continental shelf versus those in
deeper waters). The total line-kilometers for each survey, the
predominant source, the effective percentages associated with each
depth, and the effective total volume ensonified are given below (Table
9).
Calculating Volume of Water Ensonified--The cross-sectional area of
water ensonified at or above the 160 dB rms threshold was calculated
using a simple model of sound propagation loss, which accounts for the
loss of sound energy over increasing range. We used a spherical
spreading model (where propagation loss = 20 * log [range]; such that
there would be a 6-dB reduction in sound level for each doubling of
distance from the source), a reasonable approximation over the
relatively short ranges involved. Spherical spreading is a reasonable
assumption even in relatively shallow waters since, taking into account
the beam angle, the reflected energy from the seafloor will be much
weaker than the direct source and the volume influenced by the
reflected acoustic energy would be much smaller over the relatively
short ranges involved. We also accounted for the frequency-dependent
absorption coefficient and beam pattern of these sound sources, which
is generally highly directional. The lowest frequency was used for
systems that are operated over a range of frequencies. The vertical
extent of this area is calculated for two depth strata. These results,
shown in Table 9, were applied differentially based on the typical
vertical stratification of marine mammals (see Table 10).
Following the determination of effective sound exposure area for
transmissions considered in two dimensions, the next step was to
determine the effective volume of water ensonified at or above 160 dB
rms for the entirety of each survey. For each of the three predominant
sound sources, the volume of water ensonified is estimated as the
athwartship cross-sectional area (in square kilometers) of sound at or
above 160 dB rms (as illustrated in Figure 6.2 of AFSC's

[[Page 37676]]

application) multiplied by the total distance traveled by the ship.
Where different sources operating simultaneously would be predominant
in each different depth strata, the resulting cross-sectional area
calculated took this into account. Specifically, for shallow-diving
species this cross-sectional area was determined for whichever was
predominant in the shallow stratum, whereas for deeper-diving species
this area was calculated from the combined effects of the predominant
source in the shallow stratum and the (sometimes different) source
predominating in the deep stratum. This creates an effective total
volume characterizing the area ensonified when each predominant source
is operated and accounts for the fact that deeper-diving species may
encounter a complex sound field in different portions of the water
column.
Marine Mammal Densities--One of the primary limitations to
traditional estimates of behavioral harassment from acoustic exposure
is the assumption that animals are uniformly distributed in time and
space across very large geographical areas, such as those being
considered here. There is ample evidence that this is in fact not the
case, and marine species are highly heterogeneous in terms of their
spatial distribution, largely as a result of species-typical
utilization of heterogeneous ecosystem features. Some more
sophisticated modeling efforts have attempted to include species-
typical behavioral patterns and diving parameters in movement models
that more adequately assess the spatial and temporal aspects of
distribution and thus exposure to sound. While simulated movement
models were not used to mimic individual diving or aggregation
parameters in the determination of animal density in this estimation,
the vertical stratification of marine mammals based on known or
reasonably assumed diving behavior was integrated into the density
estimates used.
First, typical two-dimensional marine mammal density estimates
(animals/km\2\) were obtained from various sources for each ecosystem
area. These were estimated from marine mammal Stock Assessment Reports
and other sources (please see Table 6-10d of AFSC's application). There
are a number of caveats associated with these estimates:
(1) They are often calculated using visual sighting data collected
during one season rather than throughout the year. The time of year
when data were collected and from which densities were estimated may
not always overlap with the timing of AFSC fisheries surveys (detailed
previously in ``Detailed Description of Activities'').
(2) Marine mammal survey areas do not necessarily coincide
spatially with the entire AFSC fisheries research area boundaries.
Estimated densities from the survey areas are assumed to apply to the
entire research area.
(3) The densities used for purposes of estimating acoustic
exposures do not take into account the patchy distributions of marine
mammals in an ecosystem, at least on the moderate to fine scales over
which they are known to occur. Instead, animals are considered evenly
distributed throughout the assessed area, and seasonal movement
patterns are not taken into account.
In addition, and to account for at least some coarse differences in
marine mammal diving behavior and the effect this has on their likely
exposure to these kinds of often highly directional sound sources, a
volumetric density of marine mammals of each species was determined.
This value is estimated as the abundance averaged over the two-
dimensional geographic area of the surveys and the vertical range of
typical habitat for the population. Habitat ranges were categorized in
two generalized depth strata (0-200 m and 0 to greater than 200 m)
based on gross differences between known generally surface-associated
and typically deep-diving marine mammals (e.g., Reynolds and Rommel,
1999; Perrin et al., 2009). Animals in the shallow-diving stratum were
assumed, on the basis of empirical measurements of diving with
monitoring tags and reasonable assumptions of behavior based on other
indicators, to spend a large majority of their lives (i.e., greater
than 75 percent) at depths shallower than 200 m. Their volumetric
density and thus exposure to sound is therefore limited by this depth
boundary. In contrast, species in the deeper-diving stratum were
assumed to regularly dive deeper than 200 m and spend significant time
at these greater depths. Their volumetric density and thus potential
exposure to sound at or above the 160 dB rms threshold is extended from
the surface to 500 m, i.e., nominal maximum water depth in regions
where these surveys occur.
The volumetric densities are estimates of the three-dimensional
distribution of animals in their typical depth strata. For shallow-
diving species the volumetric density is the area density divided by
0.2 km (i.e., 200 m). For deeper diving species, the volumetric density
is the area density divided by a nominal value of 0.5 km (i.e., 500 m).
The two-dimensional and resulting three-dimensional (volumetric)
densities for each species in each ecosystem area are shown below.
Using Area of Ensonification and Volumetric Density to Estimate
Exposures--Estimates of potential incidents of Level B harassment
(i.e., potential exposure to levels of sound at or exceeding the 160 dB
rms threshold) are then calculated by using (1) the combined results
from output characteristics of each source and identification of the
predominant sources in terms of acoustic output; (2) their relative
annual usage patterns for each operational area; (3) a source-specific
determination made of the area of water associated with received sounds
at the extent of a depth boundary; and (4) determination of a
biologically-relevant volumetric density of marine mammal species in
each area. Estimates of Level B harassment by acoustic sources are the
product of the volume of water ensonified at 160 dB rms or higher for
the predominant sound source for each relevant survey and the
volumetric density of animals for each species. These annual estimates
are given below.
Most species designated as shallow divers (< 200 m depth) were
considered to be shelf and inshore species, and their lineal distance
was the extent of survey areas to 200 m in depth. However, some shallow
diving species also occur in offshore waters so the density to 200 m
depth was applied to the volumetric density of all survey tracks. These
species included gray whale; harbor porpoise (GOARA only); northern fur
seal; Steller sea lion; Dalls' porpoise; beluga whale (Bristol Bay
stock only); humpback whale, killer whales, and sei whales (BSAIRA
only); and bearded, ribbon, ringed, and spotted seals (BSAIRA only).
Ensonified volumes for deep diving species were summed for the shallow
inshore component and the deeper waters.

[[Page 37677]]

Table 9--Annual Linear Survey Kilometers for Each Vessel and its Predominant Source Within Two Depth Strata
--------------------------------------------------------------------------------------------------------------------------------------------------------
Volume Volume
Vessel Survey Line-kms Dominant source Distance 0-200 Distance > 200 ensonified (0- ensonified
m (percent) m (percent) 200 m) (200-500 m)
--------------------------------------------------------------------------------------------------------------------------------------------------------
GOARA
rrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrr
Oscar Dyson.................. Pollock summer 17,558 EK60/ME70 74 26 224.8 256.1
acoustic trawl.
Oscar Dyson.................. Pollock winter 9,540 EK60/ME70 31 69 51.2 369.3
acoustic trawl
(Shelikof Strait).
Oscar Dyson.................. Pollock winter 4,520 EK60/ME70 99 1 77.4 2.5
acoustic trawl
(Shumagin/Sanak
Islands).
Charter vessels.............. Shelf and slope 9,189 ES60 76 24 78.2 79.4
bottom trawl
groundfish.
--------------------------------------------------------------------------------------------------------------------------------------------------------
BSAIRA
rrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrr
Oscar Dyson.................. Pollock summer 25,460 EK60/ME70 91 9 400.8 128.5
acoustic trawl
(Bering Sea).
Oscar Dyson.................. Pollock winter 2,788 EK60/ME70 15 85 7.2 132.9
acoustic trawl
(Bogoslof Island).
Charter vessels.............. Aleutian Islands 3,190 ES60 61 39 21.8 44.8
shelf and slope
bottom trawl
groundfish.
Charter vessels.............. Arctic Ecosystem 2,599 ES60 100 0 29.1 0
Integrated Survey.
Charter vessels.............. Bering Sea shelf 11,200 ES60 100 0 125.4 0
bottom trawl.
Charter vessels.............. Eastern Bering Sea 1,125 ES60 0 100 0 40.5
upper continental
slope trawl summer.
Charter vessels.............. Bering Aleutian 12,288 ES60 95 5 130.7 34.5
Salmon International
Survey (BASIS).
Charter vessels.............. Northern Bering Sea 1,440 ES60 100 0 16.1 0
bottom trawl.
Charter vessels.............. Response of fish to 259 ES60 100 0 2.9 0
drop camera systems.
Fairweather.................. Acoustic research and 145 Reson 7111 100 0 20.6 0
mapping to
characterize EFH
(FISHPAC).
--------------------------------------------------------------------------------------------------------------------------------------------------------
CSBSRA
rrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrr
Charter vessels.............. Arctic Ecosystem 5,915 ES60 100 0 66.2 0
Integrated Survey.
--------------------------------------------------------------------------------------------------------------------------------------------------------

[[Page 37678]]

Next, we provide volumetric densities for marine mammals and total
estimated takes by Level B harassment, by dominant source and total,
for each stock in each of the three research areas (Tables 10-12). We
also provide a sample calculation.
We first determine the source-specific ensonified volume of water
for each relevant survey and then determine species-specific exposure
estimates for the shallow and deep (if applicable; Tables 10-12) depth
strata. First, we know the estimated source-specific cross-sectional
ensonified area within the shallow and deep strata (Table 8) and the
number of annual line-kilometers for each survey and use these values
to derive an estimated ensonified volume. Survey- and stratum-specific
exposure estimates are the product of these ensonified volumes and the
species-specific volumetric densities (Table 10).
To illustrate the process, we focus on the EK60 and the sperm whale
in the GOARA.
(1) EK60 ensonified volume; 0-200 m: 0.0173 km\2\ * 17,558 km *
0.74 = 224.8 km\3\.
(2) EK60 ensonified volume; >200 m: 0.0561 km\2\ * 17,558 km * 0.26
= 256.1 km\3\.
(3) Repeat steps 1 and 2 for each relevant survey; sum total
ensonified volumes in each depth stratum
(4) Estimated exposures to sound >=160 dB rms; sperm whale; EK60:
(0.002 sperm whales/km\3\ * 353.4 km\3\ (total ensonified volume; 0-200
m) = 0.7) + (0.002 sperm whales/km\3\ * 627.9 km\3\ (total ensonified
volume; 200-500 m) = 1.3) = 2 estimated sperm whale exposures to SPLs
>=160 dB rms resulting from use of the EK60.
(5) Repeat steps 1-4 for additional surveys with other predominant
sound sources.
Totals in Tables 10-12 represent sums across all relevant surveys/
sources rounded up to the nearest whole number. The AFSC has requested
the authorization of take indicated by rounding.

Table 10--Densities and Estimated Source-, Stratum-, and Species-Specific Annual Estimates of Level B Harassment in the GOARA
--------------------------------------------------------------------------------------------------------------------------------------------------------
Volumetric Estimated level B Estimated level B
Area density density harassment, 0-200 m harassment, >200 m
Species Shallow Deep (animals/ (animals/ -------------------------------------------- Total
km\2\) \1\ km\3\) \2\ EK60 ES60 EK60 ES60
--------------------------------------------------------------------------------------------------------------------------------------------------------
North Pacific right whale................ X .......... 0.005 0.027 0.1 ......... ......... ......... 1
Gray whale............................... X .......... 1.700 8.500 4,649.4 ......... ......... ......... 4,650
Humpback whale (CNP)..................... X .......... 0.065 0.327 115.4 ......... ......... ......... 116
Humpback whale (WNP)..................... X .......... 0.001 0.004 1.2 ......... ......... ......... 2
Minke whale.............................. X .......... 0.001 0.006 2.1 ......... ......... ......... 3
Sei whale................................ X .......... 0.000 0.000 0.01 ......... ......... ......... 1
Fin whale................................ X .......... 0.020 0.100 35.3 ......... ......... ......... 36
Blue whale............................... X .......... 0.000 0.001 0.2 ......... ......... ......... 1
Sperm whale.............................. .......... X 0.001 0.002 0.7 0.2 1.3 0.2 3
Cuvier's beaked whale.................... .......... X 0.000 0.000 0.1 0 0.1 0 1
Baird's beaked whale..................... .......... X 0.002 0.003 1.2 0.3 2.1 0.3 4
Stejneger's beaked whale................. .......... X 0.005 0.010 3.6 0.8 6.4 0.8 12
Beluga whale (Cook Inlet) \3\............ X .......... 0.200 1.000 ......... 2.5 ......... ......... 3
Pacific white-sided dolphin.............. X .......... 0.015 0.075 26.5 5.9 ......... ......... 33
Killer whale (offshore).................. X .......... 0.011 0.055 19.4 4.3 ......... ......... 24
Killer whale (west coast transient)...... X .......... 0.006 0.028 9.9 2.2 ......... ......... 13
Killer whale (AT1 transient)............. X .......... 0.001 0.004 1.2 0.3 ......... ......... 2
Killer whale (GOA/BSAI transient)........ X .......... 0.001 0.004 1.2 0.3 ......... ......... 2
Killer whale (northern resident)......... X .......... 0.003 0.013 4.4 1.0 ......... ......... 6
Killer whale (AK resident)............... X .......... 0.009 0.045 15.9 3.5 ......... ......... 20
Harbor porpoise (GOA).................... X .......... 0.200 1.000 547.0 102.9 ......... ......... 650
Harbor porpoise (SEAK)................... X .......... 0.110 0.550 300.8 56.6 ......... ......... 358
Dall's porpoise.......................... X .......... 1.600 8.000 4,375.9 823.3 ......... ......... 5,200
Northern fur seal (CA) \4\............... X .......... 0.044 0.219 119.5 22.5 ......... ......... 143
Northern fur seal (EP--winter) \5\....... X .......... 0.377 1.883 458.0 ......... ......... ......... 459
Northern fur seal (EP--summer)........... X .......... 0.116 0.582 176.7 59.9 ......... ......... 237
Steller sea lion (eastern; GOA-wide)..... X .......... 0.059 0.294 160.8 30.3 ......... ......... 192
Steller sea lion (eastern; E144)......... X .......... 0.221 1.103 603.3 113.5 ......... ......... 717
Steller sea lion (eastern; W144)......... X .......... 0.001 0.006 3.3 0.6 ......... ......... 4
Steller sea lion (western; GOA-wide)..... X .......... 0.035 0.176 96.0 18.1 ......... ......... 115

[[Page 37679]]

Steller sea lion (western; E144)......... X .......... 0.003 0.015 7.9 1.5 ......... ......... 10
Steller sea lion (western; W144)......... X .......... 0.048 0.239 130.7 24.6 ......... ......... 156
Harbor seal (Clarence Strait)............ X .......... 0.099 0.494 174.6 38.7 ......... ......... 214
Harbor seal (Dixon/Cape Decision)........ X .......... 0.057 0.283 99.9 22.1 ......... ......... 123
Harbor seal (Sitka/Chatham Strait)....... X .......... 0.046 0.232 82.0 18.2 ......... ......... 101
Harbor seal (Lynn Canal/Stephens Passage) X .......... 0.030 0.148 52.3 11.6 ......... ......... 64
Harbor seal (Glacier Bay/Icy Strait)..... X .......... 0.022 0.113 39.8 8.8 ......... ......... 49
Harbor seal (Cook Inlet/Shelikof Strait). X .......... 0.031 0.156 54.9 12.2 ......... ......... 68
Harbor seal (Prince William Sound)....... X .......... 0.061 0.303 107.2 23.7 ......... ......... 131
Harbor seal (South Kodiak)............... X .......... 0.022 0.109 38.6 8.5 ......... ......... 48
Harbor seal (North Kodiak)............... X .......... 0.009 0.472 16.7 3.7 ......... ......... 21
Northern elephant seal................... .......... X 0.020 0.045 15.9 3.5 28.3 3.6 52
--------------------------------------------------------------------------------------------------------------------------------------------------------
\1\ Sources and derivation of marine mammal density information are provided in Table 6-10d of AFSC's application.
\2\ Volumetric density estimates derived by dividing area density estimates by 0.2 km (for shallow species) or 0.5 km (for deep species), corresponding
with defined depth strata.
\3\ The EK60 is not used in areas of Cook Inlet where beluga whales may be present.
\4\ Individuals from the California stock of northern fur seals are assumed to occur only east of 144[deg]W.
\5\The EK60 is not used in winter in areas where the northern fur seal may be present.

Table 11--Densities and Estimated Source-, Stratum-, and Species-Specific Annual Estimates of Level B Harassment in the BSAIRA
--------------------------------------------------------------------------------------------------------------------------------------------------------
Volumetric Estimated level B harassment, 0- Estimated level B
Area density density 200 m harassment, >200 m
Species Shallow Deep (animals/ (animals/ ------------------------------------------------------- Total
km\2\) \1\ km\3\) \2\ EK60 ES60 7111 EK60 ES60
--------------------------------------------------------------------------------------------------------------------------------------------------------
North Pacific right whale..... X .......... 0.000 0.002 0.1 ......... ......... ......... ......... 1
Bowhead whale................. X .......... 0.017 0.085 41.5 ......... ......... ......... ......... 42
Gray whale.................... X .......... 0.380 1.900 928.5 ......... ......... ......... ......... 929
Humpback whale (CNP).......... X .......... 0.018 0.092 45.0 ......... ......... ......... ......... 45
Humpback whale (WNP).......... X .......... 0.002 0.008 3.9 ......... ......... ......... ......... 4
Minke whale................... X .......... 0.002 0.011 4.3 ......... ......... ......... ......... 5
Sei whale..................... X .......... 0.000 0.001 0.4 ......... ......... ......... ......... 1
Fin whale..................... X .......... 0.001 0.007 3.4 ......... ......... ......... ......... 4
Sperm whale................... .......... X 0.008 0.016 6.5 5.5 0.3 4.2 1.9 19
Cuvier's beaked whale......... .......... X 0.000 0.000 0.1 0.1 0 0 0 1
Baird's beaked whale.......... .......... X 0.002 0.003 1.4 1.2 0.1 0.9 0.4 4
Stejneger's beaked whale...... .......... X 0.001 0.002 1.0 0.8 0 0.6 0.3 3
Beluga whale (Bristol Bay) \3\ X .......... 0.700 3.500 ......... ......... ......... ......... ......... 0
Beluga whale (eastern Bering X .......... 0.242 0.484 493.7 419.5 24.9 ......... ......... 939
Sea).........................
Pacific white-sided dolphin... X .......... 0.005 0.027 11.0 9.4 0.6 ......... ......... 21
Killer whale (offshore)....... X .......... 0.011 0.055 22.4 19.1 1.1 ......... ......... 43
Killer whale (GOA/BSAI X .......... 0.003 0.013 5.3 4.5 0.3 ......... ......... 11
transient)...................
Killer whale (AK resident).... X .......... 0.001 0.005 2.0 1.7 0.1 ......... ......... 4
Harbor porpoise (Bering Sea).. X .......... 0.450 2.250 918.1 780.1 46.3 ......... ......... 1,745
Dall's porpoise............... X .......... 0.033 0.164 79.9 58.8 3.4 ......... ......... 143
Northern fur seal (EP--winter) X .......... 0.075 0.377 18.2 ......... ......... ......... ......... 19
\4\..........................
Northern fur seal (EP--summer) X .......... 0.215 1.075 473.6 386.6 ......... ......... ......... 861
Steller sea lion (eastern).... X .......... 0.000 0.001 0.2 0.2 ......... ......... ......... 1
Steller sea lion (western).... X .......... 0.012 0.060 29.1 21.4 ......... ......... ......... 51
Bearded seal.................. X .......... 0.394 1.968 961.5 707.4 ......... ......... ......... 1,669
Harbor seal (Aleutian Islands) X .......... 0.003 0.014 5.9 5.0 ......... ......... ......... 11
Harbor seal (Pribilof Islands) X .......... 0.000 0.001 0.2 0.2 ......... ......... ......... 1
Harbor seal (Bristol Bay)..... X .......... 0.015 0.072 29.5 25.1 ......... ......... ......... 55
Spotted seal.................. X .......... 0.601 3.006 1,125.1 827.8 ......... ......... ......... 1,953
Ringed seal................... X .......... 0.349 1.746 853.3 627.7 ......... ......... ......... 1,481

[[Page 37680]]

Ribbon seal................... X .......... 0.241 1.204 450.5 331.4 ......... ......... ......... 782
--------------------------------------------------------------------------------------------------------------------------------------------------------
\1\ Sources and derivation of marine mammal density information are provided in Table 6-10d of AFSC's application.
\2\ Volumetric density estimates derived by dividing area density estimates by 0.2 km (for shallow species) or 0.5 km (for deep species), corresponding
with defined depth strata.
\3\ Acoustic sources considered in this analysis are not used in areas of Bristol Bay where beluga whales may occur.
\4\ The ES60 is not used during winter in BSAIRA.

Table 12--Densities and Estimated Source-, Stratum-, and Species-Specific Annual Estimates of Level B Harassment in the CSBSRA
--------------------------------------------------------------------------------------------------------------------------------------------------------
Estimated
Volumetric level B
Area density density harassment, 0-
Species Shallow Deep (animals/ (animals/ 200 m Total
km\2\) \1\ km\3\) \2\ ----------------
ES60
--------------------------------------------------------------------------------------------------------------------------------------------------------
Bowhead whale................................................... X .......... 2.270 11.350 .............. 0
Gray whale...................................................... X .......... 0.010 0.050 .............. 0
Humpback whale (CNP)............................................ X .......... 0.000 0.001 .............. 0
Humpback whale (WNP)............................................ X .......... 0.000 0.000 .............. 0
Minke whale..................................................... X .......... 0.000 0.001 .............. 0
Fin whale....................................................... X .......... 0.000 0.001 .............. 0
Beluga whale (Beaufort Sea)..................................... X .......... 0.008 0.040 3.0 3
Beluga whale (eastern Chukchi Sea).............................. X .......... 0.008 0.040 3.0 3
Killer whale (GOA/BSAI transient)............................... X .......... 0.000 0.000 0.003 1
Harbor porpoise (Bering Sea).................................... X .......... 0.000 0.001 0.03 1
Bearded seal.................................................... X .......... 0.175 0.875 58.0 58
Spotted seal.................................................... X .......... 0.460 2.302 152.5 153
Ringed seal..................................................... X .......... 1.765 8.825 584.6 585
Ribbon seal..................................................... X .......... 0.184 0.922 75 62
--------------------------------------------------------------------------------------------------------------------------------------------------------
\1\ Sources and derivation of marine mammal density information are provided in Table 6-10d of AFSC's application.
\2\ Volumetric density estimates derived by dividing area density estimates by 0.2 km.

Estimated Take Due to Physical Disturbance

Take due to physical disturbance could potentially happen, as it is
likely that some pinnipeds will move or flush from known haul-outs into
the water in response to the presence or sound of AFSC vessels or
researchers. Such events could occur as a result of unintentional
approach during survey activity, in the GOARA or BSAIRA only. Physical
disturbance would result in no greater than Level B harassment.
Behavioral responses may be considered according to the scale shown in
Table 13 and based on the method developed by Mortenson (1996). We
consider responses corresponding to Levels 2-3 to constitute Level B
harassment.

Table 13--Pinniped Response to Disturbance
------------------------------------------------------------------------
Type of
Level response Definition
------------------------------------------------------------------------
1............ Alert.......... Seal head orientation or brief movement
in response to disturbance, which may
include turning head towards the
disturbance, craning head and neck
while holding the body rigid in a u-
shaped position, changing from a lying
to a sitting position, or brief
movement of less than twice the
animal's body length.
2............ Movement....... Movements away from the source of
disturbance, ranging from short
withdrawals at least twice the animal's
body length to longer retreats over the
beach.
3............ Flight......... All retreats (flushes) to the water.
------------------------------------------------------------------------

The AFSC has estimated potential incidents of Level B harassment
due to physical disturbance (Table 14) by considering the number of
seals believed to potentially be present at affected haul-outs or
rookeries and the number of visits within a certain distance of the
haul-out expected to be made by AFSC researchers. AFSC compared haul-
out and rookery locations and research survey station and track line
locations. Analysis was limited to activities that occurred within a 5-
km buffer zone from the shoreline. For point data, a 2-km zone around
the point was assumed to represent the extent of the vessel and survey
activity around the point. For line data representing the Alaska
longline survey and the Gulf of Alaska acoustic pollock survey, a 0.5
nmi (0.9 km) buffer around the line was used to represent the potential
interaction area. Take interactions where then tallied if the buffered
line or point data from the research activities intersected within a
0.5 nmi buffer zone around any identified rookery or haul-out. When on
the basis of this analysis a ``disturbance'' was assumed, the number

[[Page 37681]]

of individuals expected to be present at the location are assumed to be
disturbed. Number of individuals was determined based on count data for
Steller sea lions and based on a density value multiplied by the
buffered haul-out area for harbor seals. AFSC does not believe that any
research activities would result in physical disturbance of pinnipeds
other than Steller sea lions or harbor seals. Similarly, no disturbance
is expected of eastern Steller sea lions due to a lack of overlap
between known haul-outs or rookeries and research activities.
Although not all individuals on ``disturbed'' haul-outs would
necessarily actually be disturbed, and some haul-outs may experience
some disturbance at distances greater than expected, we believe that
this approach is a reasonable effort towards accounting for this
potential source of disturbance. The results are likely overestimates,
because some activities may only be one-time, sporadic, or biennial
activities, but are assumed to happen on an annual basis.

Table 14--Estimated Annual Level B Harassment of Pinnipeds Associated
With Disturbance by Researchers
------------------------------------------------------------------------
Estimated
Species Stock annual level B
harassment
------------------------------------------------------------------------
Harbor seal.................... Clarence Strait........ 28
Dixon/Cape Decision.... 30
Sitka/Chatham Strait... 864
Lynn Canal/Stephens 45
Passage.
Glacier Bay/Icy Strait. 20
Cook Inlet/Shelikof 2,554
Strait.
Prince William Sound... 3,063
South Kodiak........... 3,761
North Kodiak........... 885
Bristol Bay............ 132
Pribilof Islands....... 28
Aleutian Islands....... 290
Steller sea lion............... Western DPS (GOARA).... 3,082
Western DPS (BSAIRA)... 112
------------------------------------------------------------------------

Effects of Specified Activities on Subsistence Uses of Marine Mammals

The availability of the affected marine mammal stocks or species
for subsistence uses may be impacted by this activity. The subsistence
uses that may be affected and the potential impacts of the activity on
those uses are described in section 8 of the AFSC's application.
Measures included in this proposed rulemaking to reduce the impacts of
the activity on subsistence uses are described in Appendix B of the
AFSC's application. For full details, please see those documents. Last,
the information from this section and the Proposed Mitigation section
is analyzed to determine whether the necessary findings may be made in
the Unmitigable Adverse Impact Analysis and Determination section.

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, and on the
availability of such species or stock for taking for certain
subsistence uses (``least practicable adverse impact''). NMFS does not
have a regulatory definition for ``least practicable adverse impact.''
However, NMFS's implementing regulations require applicants for
incidental take authorizations to include information about the
availability and feasibility (economic and technological) of equipment,
methods, and manner of conducting such activity or other means of
effecting the least practicable adverse impact upon the affected
species or stocks and their habitat (50 CFR 216.104(a)(11)).
In evaluating how mitigation may or may not be appropriate to
ensure the least practicable adverse impact on species or stocks and
their habitat, we carefully consider two primary factors:
(1) The manner in which, and the degree to which, implementation of
the measure(s) is expected to reduce impacts to marine mammal species
or stocks, their habitat, and their availability for subsistence uses.
This analysis will consider such things as the nature of the potential
adverse impact (such as likelihood, scope, and range), the likelihood
that the measure will be effective if implemented, and the likelihood
of successful implementation.
(2) The practicability of the measure for applicant implementation.
Practicability of implementation may consider such things as cost,
impact on operations, personnel safety, and practicality of
implementation.
The following suite of mitigation measures and procedures, i.e.,
measures taken to monitor, avoid, or minimize the encounter and
potential take of marine mammals, will be employed by the AFSC during
research cruises and activities. These procedures are the same whether
the survey is conducted AFSC, IPHC, or is an AFSC-supported survey,
which may be conducted onboard a variety of vessels, e.g., on board a
NOAA vessel or charter vessel. The procedures described are based on
protocols used during previous research surveys and/or best practices
developed for commercial fisheries using similar gear. The AFSC
conducts a large variety of research operations, but only activities
using trawl, longline, and gillnet gears are expected to present a
reasonable likelihood of resulting in incidental take of marine
mammals. AFSC's past survey operations have resulted in marine mammal
interactions. These protocols are designed to continue the past record
of few interactions while providing credible, documented, and safe
encounters with observed or captured animals. Mitigation procedures
will be focused on those situations where mammals, in the best
professional judgement of the vessel operator and Chief Scientist (CS),
pose a risk of incidental take. In many instances, the AFSC will use
streamlined protocols and training for protected species

[[Page 37682]]

developed in collaboration with the North Pacific Groundfish and
Halibut Observer Program.
The AFSC has invested significant time and effort in identifying
technologies, practices, and equipment to minimize the impact of the
proposed activities on marine mammal species and stocks and their
habitat. These efforts have resulted in the consideration of many
potential mitigation measures, including those the AFSC has determined
to be feasible and has implemented in recent years as a standard part
of sampling protocols. These measures include the move-on rule
mitigation protocol (also referred to in the preamble as the move-on
rule), protected species visual watches and use of acoustic pingers on
gillnet gear and on surface trawls in southeast Alaska.
Effective monitoring is a key step in implementing mitigation
measures and is achieved through regular marine mammal watches. Marine
mammal watches are a standard part of conducting AFSC fisheries
research activities, particularly those activities that use gears that
are known to or potentially interact with marine mammals. Marine mammal
watches and monitoring occur during daylight hours prior to deployment
of gear (e.g., trawls, gillnets, and longline gear), and they continue
until gear is brought back on board. If marine mammals are sighted in
the area and are considered to be at risk of interaction with the
research gear, then the sampling station is either moved or canceled or
the activity is suspended until the marine mammals are no longer in the
area. On smaller vessels, the CS and the vessel operator are typically
those looking for marine mammals and other protected species. When
marine mammal researchers are on board (distinct from marine mammal
observers dedicated to monitoring for potential gear interactions),
they will record the estimated species and numbers of animals present
and their behavior using protocols similar or adapted from the North
Pacific Groundfish and Halibut Observer Program. If marine mammal
researchers are not on board or available, then the CS in cooperation
with the vessel operator will monitor for marine mammals and provide
training as practical to bridge crew and other crew to observe and
record such information. Because marine mammals are frequently observed
in Alaskan waters, marine mammal observations may be limited to those
animals that directly interact with or are near to the vessel or gear.
NOAA vessels, chartered vessels, and affiliated vessels or studies are
required to monitor interactions with marine mammals but are limited to
reporting direct interactions, dead animals, or entangled whales.

General Measures

Coordination and Communication--When AFSC survey effort is
conducted aboard NOAA-owned vessels, there are both vessel officers and
crew and a scientific party. Vessel officers and crew are not composed
of AFSC staff but are employees of NOAA's Office of Marine and Aviation
Operations (OMAO), which is responsible for the management and
operation of NOAA fleet ships and aircraft and is composed of uniformed
officers of the NOAA Commissioned Corps as well as civilians. The
ship's officers and crew provide mission support and assistance to
embarked scientists, and the vessel's Commanding Officer (CO) has
ultimate responsibility for vessel and passenger safety and, therefore,
decision authority. When AFSC survey effort is conducted aboard
cooperative platforms (i.e., non-NOAA vessels), ultimate responsibility
and decision authority again rests with non-AFSC personnel (i.e.,
vessel's master or captain). Decision authority includes the
implementation of mitigation measures (e.g., whether to stop deployment
of trawl gear upon observation of marine mammals). The scientific party
involved in any AFSC survey effort is composed, in part or whole, of
AFSC staff and is led by a CS. Therefore, because the AFSC--not OMAO or
any other entity that may have authority over survey platforms used by
AFSC--is the applicant to whom any incidental take authorization issued
under the authority of these proposed regulations would be issued, we
require that the AFSC take all necessary measures to coordinate and
communicate in advance of each specific survey with OMAO, or other
relevant parties, to ensure that all mitigation measures and monitoring
requirements described herein, as well as the specific manner of
implementation and relevant event-contingent decision-making processes,
are clearly understood and agreed-upon. This may involve description of
all required measures when submitting cruise instructions to OMAO or
when completing contracts with external entities. AFSC will coordinate
and conduct briefings at the outset of each survey and as necessary
between ship's crew (CO/master or designee(s), as appropriate) and
scientific party in order to explain responsibilities, communication
procedures, marine mammal monitoring protocol, and operational
procedures. The CS will be responsible for coordination with the
Officer on Deck (OOD; or equivalent on non-NOAA platforms) to ensure
that requirements, procedures, and decision-making processes are
understood and properly implemented.
As described previously, for IPHC longline survey operations,
applicable mitigation, monitoring, and reporting requirements would be
conveyed from the AFSC to the IPHC via Letters of Acknowledgement
issued by the AFSC pursuant to the MSA. Although IPHC survey effort is
not conducted aboard NOAA platforms, the same communication and
coordination requirements would apply to IPHC surveys.
Vessel Speed--Vessel speed during active sampling rarely exceeds 5
kn, with typical speeds being 2-4 kn. Transit speeds vary from 6-14 kn
but average 10 kn. These low vessel speeds minimize the potential for
ship strike (see ``Potential Effects of the Specified Activity on
Marine Mammals and Their Habitat'' for an in-depth discussion of ship
strike). In addition, when research vessels are operating in areas and
times where greater risk is expected due to marine mammal presence,
e.g., Seguam Pass during humpback whale migration, additional crew are
brought up to the bridge to monitor for whales. In such cases vessel
captains may also reduce speed to improve the chances of observing
whales and avoiding them. At any time during a survey or in transit, if
a crew member or designated marine mammal observer standing watch
sights marine mammals that may intersect with the vessel course that
individual will immediately communicate the presence of marine mammals
to the bridge for appropriate course alteration or speed reduction, as
possible, to avoid incidental collisions.
Other Gears--The AFSC deploys a wide variety of gear to sample the
marine environment during all of their research cruises. Many of these
types of gear (e.g., plankton nets, video camera and ROV deployments)
are not considered to pose any risk to marine mammals and are therefore
not subject to specific mitigation measures. However, at all times when
the AFSC is conducting survey operations at sea, the OOD and/or CS and
crew will monitor for any unusual circumstances that may arise at a
sampling site and use best professional judgment to avoid any potential
risks to marine mammals during use of all research equipment.
Handling Procedures--Handling procedures are those taken to return
a live animal to the sea or process a dead animal. The AFSC will
implement a number of handling protocols to

[[Page 37683]]

minimize potential harm to marine mammals that are incidentally taken
during the course of fisheries research activities. In general,
protocols have already been prepared for use on commercial fishing
vessels; these have been adapted from the North Pacific Fishery
Observer Manual. These procedures are expected to increase post-release
survival and, in general, following a ``common sense'' approach to
handling captured or entangled marine mammals will present the best
chance of minimizing injury to the animal and of decreasing risks to
scientists and vessel crew. Handling or disentangling marine mammals
carries inherent safety risks, and using best professional judgment and
ensuring human safety is paramount.
Captured live or injured marine mammals are released from research
gear and returned to the water as soon as possible with no gear or as
little gear remaining on the animal as possible. Animals are released
without removing them from the water if possible and data collection is
conducted in such a manner as not to delay release of the animal(s) or
endanger the crew. AFSC staff will be instructed on how to identify
different species; handle and bring marine mammals aboard a vessel;
assess the level of consciousness; remove fishing gear; and return
marine mammals to water. For further information regarding proposed
handling procedures, please see section 11.7 of AFSC's application.
Other Measures--AFSC scientists are aware of the need to prevent or
minimize disturbance of marine mammals when operating vessels nearshore
around pinniped rookeries and haul-outs, and other places where marine
mammals are aggregated. Minimum approaches shall be not less than 1 km
from the aggregation area.

Trawl Survey Visual Monitoring and Operational Protocols

Visual monitoring protocols, described above, are an integral
component of trawl mitigation protocols. Observation of marine mammal
presence and behaviors in the vicinity of AFSC trawl survey operations
allows for the application of professional judgment in determining the
appropriate course of action to minimize the incidence of marine mammal
gear interactions.
The OOD, CS or other designated member of the scientific party, and
crew standing watch on the bridge visually scan surrounding waters with
the naked eye and rangefinding binoculars (or monocular) for marine
mammals prior to, during, and until all trawl operations are completed.
Some sets may be made at night or other limited visibility conditions,
when visual observation may be conducted using the naked eye and
available vessel lighting with limited effectiveness.
Most research vessels engaged in trawling will have their station
in view for 15 minutes or 2 nmi prior to reaching the station,
depending upon the sea state and weather. Many vessels will inspect the
tow path before deploying the trawl gear, adding another 15 minutes of
observation time and gear preparation prior to deployment. Lookouts
immediately alert the OOD and CS as to their best estimate of the
species and number of animals observed and any observed animal's
distance, bearing, and direction of travel relative to the ship's
position. If any marine mammals are sighted around the vessel before
setting gear, the vessel may be moved away from the animals to a
different section of the sampling area if the animals appear to be at
risk of interaction with the gear. This is what is referred to as the
``move-on'' rule.
If marine mammals are observed at or near the station, the CS and
the vessel operator will determine the best strategy to avoid potential
takes based on the species encountered, their numbers and behavior,
their position and vector relative to the vessel, and other factors.
For instance, a whale transiting through the area and heading away from
the vessel may not require any move, or may require only a short move
from the initial sampling site, while a pod of dolphins gathered around
the vessel may require a longer move from the initial sampling site or
possibly cancellation of the station if the dolphins follow the vessel.
After moving on, if marine mammals are still visible from the vessel
and appear to be at risk, the CS may decide, in consultation with the
vessel operator, to move again or to skip the station. In many cases,
the survey design can accommodate sampling at an alternate site. In
most cases, gear is not deployed if marine mammals have been sighted
from the ship in its approach to the station unless those animals do
not appear to be in danger of interactions with the gear, as determined
by the judgment of the CS and vessel operator. The efficacy of the
``move-on'' rule is limited during night time or other periods of
limited visibility; although operational lighting from the vessel
illuminates the water in the immediate vicinity of the vessel during
gear setting and retrieval. In these cases, it is again the judgment of
the CS as based on experience and in consultation with the vessel
operator to exercise due diligence and to decide on appropriate course
of action to avoid unintentional interactions.
Once the trawl net is in the water, the OOD, CS or other designated
scientist, and/or crew standing watch continue to monitor the waters
around the vessel and maintain a lookout for marine mammals as
environmental conditions allow (as noted previously, visibility can be
limited for various reasons). If marine mammals are sighted before the
gear is fully retrieved, the most appropriate response to avoid
incidental take is determined by the professional judgment of the OOD,
in consultation with the CS and vessel operator as necessary. These
judgments take into consideration the species, numbers, and behavior of
the animals, the status of the trawl net operation (net opening, depth,
and distance from the stern), the time it would take to retrieve the
net, and safety considerations for changing speed or course. If marine
mammals are sighted during haul-back operations, there is the potential
for entanglement during retrieval of the net, especially when the trawl
doors have been retrieved and the net is near the surface and no longer
under tension. The risk of catching an animal may be reduced if the
trawling continues and the haul-back is delayed until after the marine
mammal has lost interest in the gear or left the area. The appropriate
course of action to minimize the risk of incidental take is determined
by the professional judgment of the OOD, vessel operator, and the CS
based on all situation variables, even if the choices compromise the
value of the data collected at the station. We recognize that it is not
possible to dictate in advance the exact course of action that the OOD
or CS should take in any given event involving the presence of marine
mammals in proximity to an ongoing trawl tow, given the sheer number of
potential variables, combinations of variables that may determine the
appropriate course of action, and the need to prioritize human safety
in the operation of fishing gear at sea. Nevertheless, we require a
full accounting of factors that shape both successful and unsuccessful
decisions, and these details will be fed back into AFSC training
efforts and ultimately help to refine the best professional judgment
that determines the course of action taken in any given scenario (see
further discussion in ``Proposed Monitoring and Reporting'').
If trawling operations have been suspended because of the presence
of marine mammals, the vessel will resume trawl operations (when
practicable) only when the animals are

[[Page 37684]]

believed to have departed the area. This decision is at the discretion
of the OOD/CS and is dependent on the situation.
Standard survey protocols that are expected to lessen the
likelihood of marine mammal interactions include standardized tow
durations and distances. Standard bottom trawl tow durations of not
more than 15-30 minutes at the target depth will typically be
implemented, excluding deployment and retrieval time, to reduce the
likelihood of attracting and incidentally taking marine mammals. Short
tow durations, and the resulting short tow distances (typically 1-2
nmi), decrease the opportunity for marine mammals to find the vessel
and investigate. The scientific crew will avoid dumping previous
catches when the net is being retrieved, especially when the net is at
the surface at the trawl alley. This practice of dumping fish when the
net is near the vessel may train marine mammals to expect food when the
net is retrieved and may capture the protected species.
In operations in areas of southeast Alaska deploying surface nets,
several additional measures have been employed to minimize the
likelihood of marine mammal encounters, including no offal discard
prior to or during the trawling at a station, trawling of short
duration and seldom at night, no trawling less than one kilometer from
pinniped rookeries or haul-outs, and deployment of acoustic pingers
attached on the trawl foot or head ropes. Pingers are acoustic
deterrents that are intended to deter the presence of marine mammals
and therefore decrease the probability of entanglement or unintended
capture of marine mammals.
Acoustic Deterrent Devices--Acoustic deterrent devices (pingers)
are underwater sound-emitting devices that have been shown to decrease
the probability of interactions with certain species of marine mammals
when fishing gear is fitted with the devices. Multiple studies have
reported large decreases in harbor porpoise mortality (approximately
eighty to ninety percent) in bottom-set gillnets (nets composed of
vertical panes of netting, typically set in a straight line and either
anchored to the bottom or drifting) during controlled experiments
(e.g., Kraus et al., 1997; Trippel et al., 1999; Gearin et al., 2000).
Using commercial fisheries data rather than a controlled experiment,
Palka et al. (2008) reported that harbor porpoise bycatch rates in the
northeast U.S gillnet fishery when fishing without pingers was about
two to three times higher compared to when pingers were used. After
conducting a controlled experiment in a California drift gillnet
fishery during 1996-97, Barlow and Cameron (2003) reported
significantly lower bycatch rates when pingers were used for all
cetacean species combined, all pinniped species combined, and
specifically for short-beaked common dolphins (85 percent reduction)
and California sea lions (69 percent reduction). While not a
statistically significant result, catches of Pacific white-sided
dolphins were reduced by seventy percent. Carretta et al. (2008)
subsequently examined nine years of observer data from the same drift
gillnet fishery and found that pinger use had eliminated beaked whale
bycatch. Carretta and Barlow (2011) assessed the long-term
effectiveness of pingers in reducing marine mammal bycatch in the
California drift gillnet fishery by evaluating fishery data from 1990-
2009 (with pingers in use beginning in 1996), finding that bycatch
rates of cetaceans were reduced nearly fifty percent in sets using a
sufficient number of pingers. However, in contrast to the findings of
Barlow and Cameron (2003), they report no significant difference in
pinniped bycatch.
To be effective, a pinger must emit a signal that is sufficiently
aversive to deter the species of concern, which requires that the
signal is perceived while also deterring investigation. In rare cases,
aversion may be learned as a warning when an animal has survived
interaction with gear fitted with pingers (Dawson, 1994). The
mechanisms by which pingers work in operational settings are not fully
understood, but field trials and captive studies have shown that sounds
produced by pingers are aversive to harbor porpoises (e.g., Laake et
al., 1998; Kastelein et al., 2000; Culik et al., 2001), and it is
assumed that when marine mammals are deterred from interacting with
gear fitted with pingers that it is because the sounds produced by the
devices are aversive. Two primary concerns expressed with regard to
pinger effectiveness in reducing marine mammal bycatch relate to
habituation (i.e., marine mammals may become habituated to the sounds
made by the pingers, resulting in increasing bycatch rates over time;
Dawson, 1994; Cox et al., 2001; Carlstr[ouml]m et al., 2009) and the
``dinner bell effect'' (Dawson, 1994; Richardson et al., 1995), which
implies that certain predatory marine mammal species (e.g., sea lions)
may come to associate pingers with a food source (e.g., fish caught in
nets) with the result that bycatch rates may be higher in nets with
pingers than in those without.
Palka et al. (2008) report that habituation has not occurred on a
level that affects the bycatch estimate for the northeast U.S. gillnet
fishery, while cautioning that the data studied do not provide a direct
method to study habituation. Similarly, Carretta and Barlow (2011)
report that habituation is not apparent in the California drift gillnet
fishery, with the proportion of pinger-fitted sets with bycatch not
significantly different for either cetaceans or pinnipeds between the
periods 1996-2001 and 2001-09; in fact, bycatch rates for both taxa
overall were lower in the latter period. We are not aware of any long-
term behavioral studies investigating habituation. Bycatch rates of
California sea lions, specifically, did increase during the latter
period. However, the authors do not attribute the increase to pinger
use (i.e., the ``dinner bell effect''); rather, they believe that
continuing increases in population abundance for the species (Carretta
et al., 2017) coincident with a decline in fishery effort are
responsible for the increased rate of capture. Despite these potential
limitations on the effectiveness of pingers, and while effectiveness
has not been tested on trawl gear, we believe that the available
evidence supports an assumption that use of pingers is likely to reduce
the potential for marine mammal interactions with AFSC surface trawl
gear in southeast Alaska.
If one assumes that use of a pinger is effective in deterring
marine mammals from interacting with fishing gear, one must therefore
assume that receipt of the acoustic signal has a disturbance effect on
those marine mammals (i.e., Level B harassment). However, Level B
harassment that may be incurred as a result of AFSC use of pingers does
not constitute take that must be authorized under the MMPA. The MMPA
prohibits the taking of marine mammals by U.S. citizens or within the
U.S. EEZ unless such taking is appropriately permitted or authorized.
However, the MMPA provides several narrowly defined exemptions from
this requirement (e.g., for Alaskan natives; for defense of self or
others; for Good Samaritans (16 U.S.C. 1371(b)-(d))). Section 109(h) of
the MMPA (16 U.S.C. 1379(h)) allows for the taking of marine mammals in
a humane manner by Federal, state, or local government officials or
employees in the course of their official duties if the taking is
necessary for the protection or welfare of the mammal, the protection
of the public health and welfare, or the non-lethal removal of nuisance
animals. AFSC use of pingers as a deterrent device, which may cause
Level B harassment of marine mammals, is intended solely for the
avoidance of

[[Page 37685]]

potential marine mammal interactions with AFSC research gear (i.e.,
avoidance of Level A harassment, serious injury, or mortality).
Therefore, use of such deterrent devices, and the taking that may
result, is for the protection and welfare of the mammal and is covered
explicitly under MMPA section 109(h)(1)(A). Potential taking of marine
mammals resulting from AFSC use of pingers is not discussed further in
this document.
As described above, pingers (10 kHz, 132 dB, 300 ms every 4 s)
would be deployed on surface trawl nets deployed in southeast Alaska.
Pingers would also be deployed on gillnets. Please see ``Marine Mammal
Hearing'' below for reference to functional and best hearing ranges for
marine mammals.

Longline Survey Visual Monitoring and Operational Protocols

Visual monitoring requirements for all longline surveys are similar
to the general protocols described above for trawl surveys. Please see
that section for full details of the visual monitoring protocol and the
move-on rule mitigation protocol. In summary, requirements for longline
surveys are to: (1) Conduct visual monitoring prior to arrival on
station; (2) implement the move-on rule if marine mammals are observed
within the area around the vessel and may be at risk of interacting
with the vessel or gear; (3) deploy gear as soon as possible upon
arrival on station (depending on presence of marine mammals); and (4)
maintain visual monitoring effort throughout deployment and retrieval
of the longline gear. As was described for trawl gear, the OOD, CS, or
watch leader will use best professional judgment to minimize the risk
to marine mammals from potential gear interactions during deployment
and retrieval of gear. If marine mammals are detected during setting
operations and are considered to be at risk, immediate retrieval or
suspension of operations may be warranted. If operations have been
suspended because of the presence of marine mammals, the vessel will
resume setting (when practicable) only when the animals are believed to
have departed the area. If marine mammals are detected during retrieval
operations and are considered to be at risk, haul-back may be
postponed. These decisions are at the discretion of the OOD/CS and are
dependent on the situation.
As for trawl surveys, some standard survey protocols are expected
to minimize the potential for marine mammal interactions. Soak times
are typically short relative to commercial fishing operations, measured
from the time the last hook is in the water to when the first hook is
brought out of the water. AFSC longline protocols specifically prohibit
chumming (releasing additional bait to attract target species to the
gear). Spent bait and offal are discarded away from the longline
retrieval area but not retained until completion of longline retrieval.
Due to the volume of fish caught with each set and the length of time
it takes to retrieve the longline (up to eight hours), the retention of
spent bait and offal until the gear is completely retrieved is not
possible.
Whales, particularly killer whales in the Bering Sea and sperm
whales in the Gulf of Alaska, are commonly attracted to longline
fishing operations and have learned how to remove fish from longline
gear as it is retrieved. Such depredation of fish off the longline by
whales can significantly affect catch rate and species composition of
data collected by the survey. The effect of depredation activity on
survey results has been a research subject for many years and many
aspects are therefore recorded as part of normal survey protocols,
including the amount of catch potentially depredated (percent of empty
hooks or damaged fish), number of whales visible, behavior of whales,
whale proximity to the vessel, and any whale/vessel interactions. Sperm
whale depredation can be difficult to determine because they can
alternate between diving deep to depredate the line and swimming at the
surface eating offal (see below). The presence of sperm whales at the
surface does not mean they are actively depredating the line.
The Alaska Longline Survey uses bottom longline gear with a 16-km
mainline. Sets are made in the morning if no killer whales or sperm
whales are present and the longline gear is allowed to soak for three
hours before haul-back begins. Due to the length of the mainline and
numbers of hooks involved, it takes up to eight hours to complete the
haul-back. Whales have learned to associate particular sounds with
longline operations and typically arrive on scene as the gear is being
retrieved. Efforts have been made to avoid depredation by allowing the
line to sink back down but such strategies have proved impractical as
whales can wait in the area for days and fish caught on the line are
then eaten by other demersal marine organisms. The only practical way
to minimize depredation if whales find the vessel is to continue
retrieving the gear as quickly as possible. As killer whales may also
follow the survey vessel between stations, the station order has been
altered to disrupt the survey pattern as a means to dissuade the
animals from this behavior and to avoid continued interactions.

Gillnet Survey Visual Monitoring and Operational Protocols

Visual monitoring and operational protocols for gillnet surveys are
similar to those described previously for trawl surveys, with a focus
on visual observation in the survey area and avoidance of marine
mammals that may be at risk of interaction with survey vessels or gear.
Gillnets are not deployed if marine mammals have been sighted on
arrival at the sample site. The exception is for animals that, because
of their behavior, travel vector or other factors, do not appear to be
at risk of interaction with the gillnet gear. If no marine mammals are
present, the gear is set and monitored continuously during the soak. If
a marine mammal is sighted during the soak and appears to be at risk of
interaction with the gear, then the gear is pulled immediately. As
noted above, pingers would be deployed on gillnets, which are used only
at the Little Port Walter Research Station in southeast Alaska and in
Prince William Sound.
We have carefully evaluated the AFSC's proposed mitigation measures
and considered a range of other measures in the context of ensuring
that we prescribed the means of effecting the least practicable adverse
impact on the affected marine mammal species and stocks and their
habitat. Based on our evaluation of these measures, we have
preliminarily determined that the proposed mitigation measures provide
the means of effecting the least practicable adverse impact on marine
mammal species or stocks and their habitat, paying particular attention
to rookeries, mating grounds, and areas of similar significance, and on
the availability of such species or stock for subsistence uses.

Proposed Monitoring and Reporting

In order to issue an LOA 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 the authorized taking. NMFS's MMPA
implementing regulations further describe the information that an
applicant should provide when requesting an authorization (50 CFR
216.104(a)(13)), including the means of accomplishing the necessary
monitoring and reporting that will result in increased knowledge of the
species and the level of taking or impacts on populations of marine
mammals.
Monitoring and reporting requirements prescribed by NMFS

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should contribute to improved understanding of one or more of the
following:
Occurrence of significant interactions with marine mammal
species in action area (e.g., animals that came close to the vessel,
contacted the gear, or are otherwise rare or displaying unusual
behavior).
Nature, scope, or context of likely marine mammal exposure
to potential stressors/impacts (individual or cumulative, acute or
chronic), through better understanding of: (1) Action or environment
(e.g., source characterization, propagation, ambient noise); (2)
affected species (e.g., life history, dive patterns); (3) co-occurrence
of marine mammal species with the action; or (4) biological or
behavioral context of exposure (e.g., age, calving or feeding areas).
Individual marine mammal responses (behavioral or
physiological) to acoustic stressors (acute, chronic, or cumulative),
other stressors, or cumulative impacts from multiple stressors.
How anticipated responses to stressors impact either: (1)
Long-term fitness and survival of individual marine mammals; or (2)
populations, species, or stocks.
Effects on marine mammal habitat (e.g., marine mammal prey
species, acoustic habitat, or important physical components of marine
mammal habitat).
Mitigation and monitoring effectiveness.
AFSC plans to make more systematic its training, operations, data
collection, animal handling and sampling protocols, etc. in order to
improve its ability to understand how mitigation measures influence
interaction rates and ensure its research operations are conducted in
an informed manner and consistent with lessons learned from those with
experience operating these gears in close proximity to marine mammals.
It is in this spirit that we propose the monitoring requirements
described below.

Visual Monitoring

Marine mammal watches are a standard part of conducting fisheries
research activities, and are implemented as described previously in
``Proposed Mitigation.'' Dedicated marine mammal visual monitoring
occurs as described (1) for some period prior to deployment of most
research gear; (2) throughout deployment and active fishing of all
research gears; (3) for some period prior to retrieval of longline
gear; and (4) throughout retrieval of all research gear. This visual
monitoring is performed by trained AFSC personnel or other trained crew
during the monitoring period. Observers record the species and
estimated number of animals present and their behaviors, which may be
valuable information towards an understanding of whether certain
species may be attracted to vessels or certain survey gears.
Separately, marine mammal watches are conducted by watch-standers
(those navigating the vessel and other crew; these will typically not
be AFSC personnel) at all times when the vessel is being operated. The
primary focus for this type of watch is to avoid striking marine
mammals and to generally avoid navigational hazards. These watch-
standers typically have other duties associated with navigation and
other vessel operations and are not required to record or report to the
scientific party data on marine mammal sightings, except when gear is
being deployed or retrieved.
AFSC will also monitor disturbance of hauled-out pinnipeds
resulting from the presence of researchers, paying particular attention
to the distance at which different species of pinniped are disturbed.
Disturbance will be recorded according to the three-point scale,
representing increasing seal response to disturbance, shown in Table
13.

Training

AFSC anticipates that additional information on practices to avoid
marine mammal interactions can be gleaned from training sessions and
more systematic data collection standards. The AFSC will conduct annual
trainings for all chief scientists and other personnel who may be
responsible for conducting marine mammal visual observations or
handling incidentally captured marine mammals to explain mitigation
measures and monitoring and reporting requirements, mitigation and
monitoring protocols, marine mammal identification, recording of count
and disturbance observations, completion of datasheets, and use of
equipment. Some of these topics may be familiar to AFSC staff, who may
be professional biologists; the AFSC shall determine the agenda for
these trainings and ensure that all relevant staff have necessary
familiarity with these topics. The AFSC will work with the North
Pacific Fisheries Groundfish and Halibut Observer Program to customize
a new training program. The first such training will include three
primary elements: (1) An overview of the purpose and need for the
authorization, including mandatory mitigation measures by gear and the
purpose for each, and species that AFSC is authorized to incidentally
take; (2) detailed descriptions of reporting, data collection, and
sampling protocols; and (3) discussion of best professional judgment
(which is recognized as an integral component of mitigation
implementation; see ``Proposed Mitigation'').
The second topic will include instruction on how to complete new
data collection forms such as the marine mammal watch log, the
incidental take form (e.g., specific gear configuration and details
relevant to an interaction with protected species), and forms used for
species identification and biological sampling.
The third topic will include use of professional judgment in any
incidents of marine mammal interaction and instructive examples where
use of best professional judgment was determined to be successful or
unsuccessful. We recognize that many factors come into play regarding
decision-making at sea and that it is not practicable to simplify what
are inherently variable and complex situational decisions into rules
that may be defined on paper. However, it is our intent that use of
best professional judgment be an iterative process from year to year,
in which any at-sea decision-maker (i.e., responsible for decisions
regarding the avoidance of marine mammal interactions with survey gear
through the application of best professional judgment) learns from the
prior experience of all relevant AFSC personnel (rather than from
solely their own experience). The outcome should be increased
transparency in decision-making processes where best professional
judgment is appropriate and, to the extent possible, some degree of
standardization across common situations, with an ultimate goal of
reducing marine mammal interactions. It is the responsibility of the
AFSC to facilitate such exchange.

Handling Procedures and Data Collection

Improved standardization of handling procedures were discussed
previously in ``Proposed Mitigation.'' In addition to the benefits
implementing these protocols are believed to have on the animals
through increased post-release survival, AFSC believes adopting these
protocols for data collection will also increase the information on
which ``serious injury'' determinations (NMFS, 2012a, 2012b) are based
and improve scientific knowledge about marine mammals that interact
with fisheries research gears and the factors that contribute to these
interactions. AFSC personnel will be provided standard guidance and
training regarding handling of marine mammals, including how to
identify different species, bring an individual aboard a vessel, assess
the

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level of consciousness, remove fishing gear, return an individual to
water and log activities pertaining to the interaction.
AFSC will record interaction information on their own standardized
forms. To aid in serious injury determinations and comply with the
current NMFS Serious Injury Guidelines (NMFS, 2012a, 2012b),
researchers will also answer a series of supplemental questions on the
details of marine mammal interactions.
Finally, for any marine mammals that are killed during fisheries
research activities, scientists will collect data and samples pursuant
to Appendix D of the AFSC DEA, ``Protected Species Mitigation and
Handling Procedures for AFSC Fisheries Research Vessels.''

Reporting

As is normally the case, AFSC will coordinate with the relevant
stranding coordinators for any unusual marine mammal behavior and any
stranding, beached live/dead, or floating marine mammals that are
encountered during field research activities. The AFSC will follow a
phased approach with regard to the cessation of its activities and/or
reporting of such events, as described in the proposed regulatory texts
following this preamble. In addition, Chief Scientists (or cruise
leader, CS) will provide reports to AFSC leadership and to the Office
of Protected Resources (OPR). As a result, when marine mammals interact
with survey gear, whether killed or released alive, a report provided
by the CS will fully describe any observations of the animals, the
context (vessel and conditions), decisions made and rationale for
decisions made in vessel and gear handling. The circumstances of these
events are critical in enabling AFSC and OPR to better evaluate the
conditions under which takes are most likely occur. We believe in the
long term this will allow the avoidance of these types of events in the
future.
The AFSC will submit annual summary reports to OPR including: (1)
Annual line-kilometers surveyed during which the EK60, ME70, ES60, 7111
(or equivalent sources) were predominant (see ``Estimated Take by
Acoustic Harassment'' for further discussion), specific to each region;
(2) summary information regarding use of all longline, gillnet, and
trawl gear, including number of sets, tows, etc., specific to each
research area and gear; (3) accounts of all incidents of marine mammal
interactions, including circumstances of the event and descriptions of
any mitigation procedures implemented or not implemented and why; (4)
summary information related to any disturbance of pinnipeds, including
event-specific total counts of animals present, counts of reactions
according to the three-point scale shown in Table 13, and distance of
closest approach; and (5) a written evaluation of the effectiveness of
AFSC mitigation strategies in reducing the number of marine mammal
interactions with survey gear, including best professional judgment and
suggestions for changes to the mitigation strategies, if any. The
period of reporting will be annually, beginning one year post-issuance
of any LOA, and the report must be submitted not less than ninety days
following the end of a given year. Submission of this information is in
service of an adaptive management framework allowing NMFS to make
appropriate modifications to mitigation and/or monitoring strategies,
as necessary, during the proposed five-year period of validity for
these regulations.
NMFS has established a formal incidental take reporting system, the
Protected Species Incidental Take (PSIT) database, requiring that
incidental takes of protected species be reported within 48 hours of
the occurrence. The PSIT generates automated messages to NMFS
leadership and other relevant staff, alerting them to the event and to
the fact that updated information describing the circumstances of the
event has been inputted to the database. The PSIT and CS reports
represent not only valuable real-time reporting and information
dissemination tools but also serve as an archive of information that
may be mined in the future to study why takes occur by species, gear,
region, etc.
AFSC will also collect and report all necessary data, to the extent
practicable given the primacy of human safety and the well-being of
captured or entangled marine mammals, to facilitate serious injury (SI)
determinations for marine mammals that are released alive. AFSC will
require that the CS complete data forms and address supplemental
questions, both of which have been developed to aid in SI
determinations. AFSC understands the critical need to provide as much
relevant information as possible about marine mammal interactions to
inform decisions regarding SI determinations. In addition, the AFSC
will perform all necessary reporting to ensure that any incidental M/SI
is incorporated as appropriate into relevant SARs.

Negligible Impact Analysis and Determination

Introduction--NMFS has defined negligible impact 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 (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. In addition to considering estimates of the number of
marine mammals that might be ``taken'' by mortality, serious injury,
and Level A or Level B harassment, we consider other factors, such as
the likely nature of any behavioral responses (e.g., intensity,
duration), the context of any such responses (e.g., critical
reproductive time or location, migration), as well as effects on
habitat, and the likely effectiveness of mitigation. We also assess the
number, intensity, and context of estimated takes by evaluating this
information relative to population status. Consistent with the 1989
preamble for NMFS's implementing regulations (54 FR 40338; September
29, 1989), the impacts from other past and ongoing anthropogenic
activities are incorporated into this analysis via their impacts on the
environmental baseline (e.g., as reflected in the regulatory status of
the species, population size and growth rate where known, ongoing
sources of human-caused mortality, and specific consideration of take
by M/SI previously authorized for other NMFS research activities).
We note here that the takes from potential gear interactions
enumerated below could result in non-serious injury, but their worse
potential outcome (mortality) is analyzed for the purposes of the
negligible impact determination. We discuss here the connection between
the mechanisms for authorizing incidental take under section 101(a)(5)
for activities, such as AFSC's research activities, and for authorizing
incidental take from commercial fisheries. In 1988, Congress amended
the MMPA's provisions for addressing incidental take of marine mammals
in commercial fishing operations. Congress directed NMFS to develop and
recommend a new long-term regime to govern such incidental taking (see
MMC, 1994). The need to develop a system suited to the unique
circumstances of commercial fishing operations led NMFS to suggest a
new conceptual means and associated regulatory framework. That concept,
Potential Biological Removal (PBR), and

[[Page 37688]]

a system for developing plans containing regulatory and voluntary
measures to reduce incidental take for fisheries that exceed PBR were
incorporated as sections 117 and 118 in the 1994 amendments to the
MMPA.
PBR is defined in the MMPA (16 U.S.C. 1362(20)) as the maximum
number of animals, not including natural mortalities, that may be
removed from a marine mammal stock while allowing that stock to reach
or maintain its optimum sustainable population, and is a measure to be
considered when evaluating the effects of M/SI on a marine mammal
species or stock. Optimum sustainable population (OSP) is defined by
the MMPA (16 U.S.C. 1362(9)) as the number of animals which will result
in the maximum productivity of the population or the species, keeping
in mind the carrying capacity of the habitat and the health of the
ecosystem of which they form a constituent element. A primary goal of
the MMPA is to ensure that each species or stock of marine mammal is
maintained at or returned to its OSP.
PBR values are calculated by NMFS as the level of annual removal
from a stock that will allow that stock to equilibrate within OSP at
least 95 percent of the time, and is the product of factors relating to
the minimum population estimate of the stock (Nmin); the
productivity rate of the stock at a small population size; and a
recovery factor. Determination of appropriate values for these three
elements incorporates significant precaution, such that application of
the parameter to the management of marine mammal stocks may be
reasonably certain to achieve the goals of the MMPA. For example,
calculation of Nmin incorporates the precision and
variability associated with abundance information and is intended to
provide reasonable assurance that the stock size is equal to or greater
than the estimate (Barlow et al., 1995). In general, the three factors
are developed on a stock-specific basis in consideration of one another
in order to produce conservative PBR values that appropriately account
for both imprecision that may be estimated as well as potential bias
stemming from lack of knowledge (Wade, 1998).
PBR can be used as a consideration of the effects of M/SI on a
marine mammal stock but was applied specifically to work within the
management framework for commercial fishing incidental take. PBR cannot
be applied appropriately outside of the section 118 regulatory
framework for which it was designed without consideration of how it
applies in section 118 and how other statutory management frameworks in
the MMPA differ. PBR was not designed as an absolute threshold limiting
commercial fisheries, but rather as a means to evaluate the relative
impacts of those activities on marine mammal stocks. Even where
commercial fishing is causing M/SI at levels that exceed PBR, the
fishery is not suspended. When M/SI exceeds PBR, NMFS may develop a
take reduction plan, usually with the assistance of a take reduction
team. The take reduction plan will include measures to reduce and/or
minimize the taking of marine mammals by commercial fisheries to a
level below the stock's PBR. That is, where the total annual human-
caused M/SI exceeds PBR, NMFS is not required to halt fishing
activities contributing to total M/SI but rather utilizes the take
reduction process to further mitigate the effects of fishery activities
via additional bycatch reduction measures. PBR is not used to grant or
deny authorization of commercial fisheries that may incidentally take
marine mammals.
Similarly, to the extent consideration of PBR may be relevant to
considering the impacts of incidental take from activities other than
commercial fisheries, using it as the sole reason to deny incidental
take authorization for those activities would be inconsistent with
Congress's intent under section 101(a)(5) and the use of PBR under
section 118. The standard for authorizing incidental take under section
101(a)(5) continues to be, among other things, whether the total taking
will have a negligible impact on the species or stock. When Congress
amended the MMPA in 1994 to add section 118 for commercial fishing, it
did not alter the standards for authorizing non-commercial fishing
incidental take under section 101(a)(5), acknowledging that negligible
impact under section 101(a)(5) is a separate standard from PBR under
section 118. In fact, in 1994 Congress also amended section
101(a)(5)(E) (a separate provision governing commercial fishing
incidental take for species listed under the Endangered Species Act) to
add compliance with the new section 118 but kept the requirement for a
negligible impact finding, showing that the determination of negligible
impact and application of PBR may share certain features but are
different.
Since the introduction of PBR, NMFS has used the concept almost
entirely within the context of implementing sections 117 and 118 and
other commercial fisheries management-related provisions of the MMPA.
The MMPA requires that PBR be estimated in stock assessment reports and
that it be used in applications related to the management of take
incidental to commercial fisheries (i.e., the take reduction planning
process described in section 118 of the MMPA and the determination of
whether a stock is ``strategic'' (16 U.S.C. 1362(19))), but nothing in
the MMPA requires the application of PBR outside the management of
commercial fisheries interactions with marine mammals.
Nonetheless, NMFS recognizes that as a quantitative metric, PBR may
be useful in certain instances as a consideration when evaluating the
impacts of other human-caused activities on marine mammal stocks.
Outside the commercial fishing context, and in consideration of all
known human-caused mortality, PBR can help inform the potential effects
of M/SI caused by activities authorized under 101(a)(5)(A) on marine
mammal stocks. As noted by NMFS and the USFWS in our implementation
regulations for the 1986 amendments to the MMPA (54 FR 40341, September
29, 1989), the Services consider many factors, when available, in
making a negligible impact determination, including, but not limited
to, the status of the species or stock relative to OSP (if known),
whether the recruitment rate for the species or stock is increasing,
decreasing, stable, or unknown, the size and distribution of the
population, and existing impacts and environmental conditions. To
specifically use PBR, along with other factors, to evaluate the effects
of M/SI, we first calculate a metric for each species or stock that
incorporates information regarding ongoing anthropogenic M/SI into the
PBR value (i.e., PBR minus the total annual anthropogenic mortality/
serious injury estimate), which is called ``residual PBR'' (Wood et
al., 2012). We then consider how the anticipated potential incidental
M/SI from the activities being evaluated compares to residual PBR.
Anticipated or potential M/SI that exceeds residual PBR is considered
to have a higher likelihood of adversely affecting rates of recruitment
or survival, while anticipated M/SI that is equal to or less than
residual PBR has a lower likelihood (both examples given without
consideration of other types of take, which also factor into a
negligible impact determination). In such cases where the anticipated
M/SI is near, at, or above residual PBR, consideration of other
factors, including those outlined above as well as mitigation and other
factors (positive or negative), is especially important to assessing
whether the M/SI will have a negligible impact on the stock. As
described above, PBR is a conservative metric and

[[Page 37689]]

is not intended to be used as a solid cap on mortality--accordingly,
impacts from M/SI that exceed residual PBR may still potentially be
found to be negligible in light of other factors that offset concern,
especially when robust mitigation and adaptive management provisions
are included.
Alternately, for a species or stock with incidental M/SI less than
10 percent of residual PBR, we consider M/SI from the specified
activities to represent an insignificant incremental increase in
ongoing anthropogenic M/SI that alone (i.e., in the absence of any
other take) cannot affect annual rates of recruitment and survival. In
a prior incidental take rulemaking and in the commercial fishing
context, this threshold is identified as the significance threshold,
but it is more accurately an insignificance threshold outside
commercial fishing because it represents the level at which there is no
need to consider other factors in determining the role of M/SI in
affecting rates of recruitment and survival. Assuming that any
additional incidental take by harassment would not exceed the
negligible impact level, the anticipated M/SI caused by the activities
being evaluated would have a negligible impact on the species or stock.
This 10 percent was identified as a workload simplification
consideration to avoid the need to provide unnecessary additional
information when the conclusion is relatively obvious; but as described
above, values above 10 percent have no particular significance
associated with them until and unless they approach residual PBR.
Our evaluation of the M/SI for each of the species and stocks for
which mortality could occur follows. In addition, all mortality
authorized for some of the same species or stocks over the next several
years pursuant to our final rulemakings for the NMFS Southwest
Fisheries Science Center and the NMFS Northwest Fisheries Science
Center has been incorporated into the residual PBR.
We first consider maximum potential incidental M/SI for each stock
(Table 6) in consideration of NMFS's threshold for identifying
insignificant M/SI take (10 percent of residual PBR (69 FR 43338; July
20, 2004)). By considering the maximum potential incidental M/SI in
relation to PBR and ongoing sources of anthropogenic mortality, we
begin our evaluation of whether the potential incremental addition of
M/SI through AFSC research activities may affect the species' or
stock's annual rates of recruitment or survival. We also consider the
interaction of those mortalities with incidental taking of that species
or stock by harassment pursuant to the specified activity.

Summary of Estimated Incidental Take

Here we provide a summary of the total proposed incidental take
authorization on an annual basis, as well as other information relevant
to the negligible impact analysis. Table 15 shows information relevant
to our negligible impact analysis concerning the total annual taking
that could occur for each stock from NMFS' scientific research
activities when considering incidental take previously authorized for
SWFSC (80 FR 58982; September 30, 2015) and take proposed for
authorization for NWFSC (81 FR 38516; June 13, 2016) and AFSC.
Scientific research activities conducted by the SWFSC and/or NWFSC may
impact the same populations of marine mammals expected to be impacted
by IPHC survey activities occurring off of the U.S. west coast. We
propose to authorize take by M/SI over the five-year period of validity
for these proposed regulations as indicated in Table 15 below. For the
purposes of the negligible impact analysis, we assume that all of these
takes could potentially be in the form of M/SI; PBR is not appropriate
for direct assessment of the significance of harassment.
For some stocks, a range is provided in the ``Total M/SI
Authorization'' columns of Table 15 (below). In these cases, the worst
case potential outcome is used to derive the value presented in the
``Estimated Maximum Annual M/SI'' column (Table 15, below). For
example, we present ranges of 13-18 and 3-8 as the total take
authorization proposed over five years for the eastern Pacific and
California stocks of northern fur seal, respectively. These ranges
reflect that, as part of the overall proposed take authorization for
AFSC, a total of five takes of northern fur seals are expected to occur
as a result specifically of IPHC longline operations. These five takes
are considered as potentially accruing to either stock; therefore, we
assess the consequences of the proposed take authorization for these
stocks as though the maximum could occur to both. The ten total takes
expected to potentially occur as a result of SWFSC and/or NWFSC survey
operations could also occur to individuals from either stock.
Similarly, we assume that IPHC survey operations specifically could
result in incidental take of up to five harbor seals over the five
years, and that these takes could occur for any stock of harbor seal
(but that no more than one take would be expected from any given
stock). Therefore, although only five takes are expected from IPHC
activities, we assume that one take accrues to each of the 17 harbor
seal stocks that may overlap with the IPHC surveys. For the NWFSC, we
assumed that nine total takes of harbor seal could occur over five
years, and that these takes could occur to either the California or
Oregon/Washington coast stocks. Over five years, six total takes were
expected to result from NWFSC/SWFSC survey operations within Washington
inland waters--potentially occurring to any of the three stocks of
harbor seals occurring in those waters. The value presented for
``Estimated Maximum Annual M/SI'' for each stock reflects these
considerations. Similar considerations result in the ranges given for
Steller sea lions (Table 15). This stock-specific accounting does not
change our expectations regarding the combined total number of takes
that would actually occur for each stock, but informs our stock-
specific negligible impact analysis.
We previously authorized take of marine mammals incidental to
fisheries research operations conducted by the SWFSC (see 80 FR 58982
and 80 FR 68512), and proposed to authorize take incidental to
fisheries research operations conducted by the NWFSC (see 81 FR 38516).
This take would occur to some of the same stocks for which we propose
to authorize take incidental to AFSC fisheries research operations.
Therefore, in order to evaluate the likely impact of the take by M/SI
proposed for authorization in this rule, we consider not only other
ongoing sources of human-caused mortality but the potential mortality
authorized or proposed for authorization for SWFSC/NWFSC. As used in
this document, other ongoing sources of human-caused (anthropogenic)
mortality refers to estimates of realized or actual annual mortality
reported in the SARs and does not include authorized or unknown
mortality. Below, we consider the total taking by M/SI proposed for
authorization for AFSC and previously authorized or proposed for
authorization for SWFSC/NWFSC together to produce a maximum annual M/SI
take level (including take of unidentified marine mammals that could
accrue to any relevant stock) and compare that value to the stock's PBR
value, considering ongoing sources of anthropogenic mortality (as
described in footnote 4 of Table 15 and in the following discussion).
PBR and annual M/SI values considered in Table 15 reflect the most
recent information available (i.e., final 2016 SARs).

[[Page 37690]]

Table 15--Summary Information Related to AFSC Proposed Annual Take Authorization, 2018-23
--------------------------------------------------------------------------------------------------------------------------------------------------------
Proposed total Proposed AFSC/
annual Level B Percent of IPHC total M/ SWFSC/NWFSC Estimated PBR minus Stock
Species 1 Stock harassment estimated SI total M/SI maximum annual M/SI trend 6
authorization population authorization, authorization annual M/ (%) 5
2 abundance 2018-23 3 SI 4
--------------------------------------------------------------------------------------------------------------------------------------------------------
North Pacific right whale...... ENP............... 2 6.5............ 0 0 0 n/a ?
Bowhead whale.................. Western Arctic.... 42 0.2............ 0 0 0 n/a [uarr]
Gray whale..................... ENP............... 5,579 26.6........... 0 0 0 n/a [rarr]
Humpback whale................. CNP............... 161 1.6............ 0 0 0 n/a [uarr]
WNP............... 6 0.5............ 0 0 0 n/a [uarr]
Minke whale.................... Alaska............ 8 0.2 \8\........ 0 0 0 n/a ?
Sei whale...................... ENP............... 2 0.4............ 0 0 0 n/a [uarr]
Fin whale...................... Northeast Pacific. 40 3.9 \8\........ 0 0 0 n/a [uarr]
Blue whale..................... ENP............... 1 0.1............ 0 0 0 n/a [rarr]
Sperm whale.................... North Pacific..... 22 Unknown........ 2 0 0.4 ? ?
Cuvier's beaked whale.......... Alaska............ 2 Unknown........ 0 0 0 n/a ?
Baird's beaked whale........... Alaska............ 8 Unknown........ 0 0 0 n/a ?
Stejneger's beaked whale....... Alaska............ 15 Unknown........ 0 0 0 n/a ?
Beluga whale................... Beaufort Sea...... 3 0.0............ 1 0 0.2 510 (0.0) [uarr] or
[rarr]
Eastern Chukchi 3 0.1............ 1 0 0.2 177 (0.1) ?
Sea.
Eastern Bering Sea 939 4.9............ 0 0 0 n/a ?
Bristol Bay....... 0 n/a............ 0 0 0 n/a [uarr]
Cook Inlet........ 3 1.0............ 0 0 0 n/a [darr]
Bottlenose dolphin............. CA/OR/WA Offshore. 0 n/a............ 1 11 2.8 9.4 (29.8) ?
Common dolphin................. CA/OR/WA.......... 0 n/a............ 1 15 3.6 8,353 (0.0) [uarr]
Pacific white-sided dolphin.... NP................ 54 0.2............ 6 0 1.6 ? ?
Risso's dolphin................ CA/OR/WA.......... 0 n/a............ 1 20 4.6 42.3 (10.9) ?
Killer whale................... ENP Offshore...... 67 27.9........... 0 0 n/a n/a ?
West Coast 13 5.3............ 0 0 n/a n/a [uarr]
Transient.
AT1 Transient..... 2 28.6........... 0 0 n/a n/a [darr]
ENP Gulf of 14 2.4............ 0 0 n/a n/a [rarr]
Alaska, Aleutian
Islands, and
Bering Sea
Transient.
ENP Northern 6 2.3............ 0 0 n/a n/a [uarr]
Resident.
ENP Alaska 24 1.0............ 2 0 0.4 23 (1.7) [uarr]
Resident.
Short-finned pilot whale....... CA/OR/WA.......... 0 n/a............ 1 2 0.6 3.3 (18.2) ?
Harbor porpoise................ Southeast Alaska.. 358 12.4 \8\....... 1 0 0.2 ? [darr] or
[rarr]
Gulf of Alaska.... 650 2.1............ 2 0 0.8 ? ?
Bering Sea........ 1,746 3.6............ 1 0 0.4 ? ?
Dall's porpoise................ CA/OR/WA.......... 0 n/a............ 1 8 2.2 171.7 (1.3) ?
Alaska............ 5,343 6.4............ 14 0 3.4 ? ?
Northern fur seal.............. Pribilof Islands/ 1,576 0.3............ 13-18 10 7.0 11,166 (0.1) [darr]
Eastern Pacific.
California........ 143 1.0............ 3-8 .............. 4.6 449.2 (1.0) [uarr]
California sea lion............ United States..... 0 n/a............ 1 35 8.0 8,811 (0.1) [uarr]
Steller sea lion............... Eastern U.S....... 914 2.2............ 7-12 19 7.4 2,390 (0.3) [uarr]
Western U.S....... 3,526 6.9............ 13-18 0 4.6 79 (5.8) ? \7\
Bearded seal................... Alaska (Beringia 1,727 0.6............ 2 0 0.8 7,819 (0.0) ?
DPS).
Harbor seal.................... California........ 0 n/a............ 1 5-14 3.6 1,598 (0.2) [rarr]
OR/WA Coast....... 0 n/a............ 1 2-11 2.2 ? [rarr]
Washington Inland 0 n/a............ 1 6 1.6 ? [rarr]
Waters.
Clarence Strait... 242 0.8............ 2 0 0.8 1,181 (0.1) [uarr]
Dixon/Cape 153 0.8............ 2 0 0.8 634 (0.1) [uarr]
Decision.
Sitka/Chatham 965 6.5............ 3 0 1.0 483 (0.2) [uarr]
Strait.
Lynn Canal/ 109 1.2............ 2 0 0.8 105 (0.8) [darr]
Stephens Passage.
Glacier Bay/Ice 69 1.0............ 2 0 0.8 65 (1.2) [uarr]
Strait.
Cook Inlet/ 2,622 9.6............ 2 0 0.8 536 (0.1) [uarr]
Shelikof Strait.
Prince William 3,194 10.7........... 3 0 1.0 559 (0.2) [darr]
Sound.
South Kodiak...... 3,809 19.8........... 2 0 0.8 186 (0.4) [darr]
North Kodiak...... 906 10.9........... 2 0 0.8 261 (0.3) [uarr]
Bristol Bay....... 187 0.6............ 2 0 0.8 1,040 (0.1) [uarr]
Pribilof Islands.. 29 12.5........... 2 0 0.8 7 (11.4) [rarr]
Aleutian Islands.. 301 4.7............ 2 0 0.8 83 (1.0) [uarr]
Spotted seal................... Alaska............ 2,106 0.5............ 3 0 1.2 12,368 (0.0) ?
Ringed seal.................... Alaska............ 2,066 1.2 \8\........ 4 0 1.6 ? ?
Ribbon seal.................... Alaska............ 1,404 0.8............ 2 0 0.8 9,781.2 ?
(0.0)
Northern elephant seal......... California 52 0.0............ 1 10 2.6 4,873.2 [uarr]
Breeding. (0.1)
--------------------------------------------------------------------------------------------------------------------------------------------------------
Please see Tables 7, 10, 11, 12, and 14 and preceding text for details.
\1\ For some species with multiple stocks, indicated level of take could occur to individuals from any stock (as indicated in table). For some stocks, a
range is presented.
\2\ Level B harassment totals include estimated take due to acoustic harassment and, for harbor seals and Steller sea lions, estimated take due to
physical disturbance. Active acoustic devices are not used for data acquisition by IPHC; therefore, no takes by acoustic harassment are expected for
stocks that occur entirely outside of Alaskan waters.
\3\ As explained earlier in this document, gear interaction could result in mortality, serious injury, or Level A harassment. Because we do not have
sufficient information to enable us to parse out these outcomes, we present such take as a pool. For purposes of this negligible impact analysis we
assume the worst case scenario (that all such takes incidental to research activities result in mortality).
\4\ This column represents the total number of incidents of M/SI that could potentially accrue to the specified species or stock as a result of NMFS's
fisheries research activities and is the number carried forward for evaluation in the negligible impact analysis (later in this document). To reach
this total, we add one to the total for each pinniped that may be captured in trawl gear in each of the three AFSC research areas; one to the total
for each pinniped that may be captured in AFSC longline gear in the GOARA and BSAIRA; and one to the total for each pinniped that may be captured in
IPHC longline gear. We also add one to the total of each small cetacean that may be captured in trawl gear in the GOARA and BSAIRA and one to the
total of each small cetacean that may be captured in gillnet gear (GOARA only). This represents the potential that the take of an unidentified
pinniped or small cetacean could accrue to any given stock captured in that gear in that area. The proposed take authorization is formulated as a five-
year total; the annual average is used only for purposes of negligible impact analysis. We recognize that portions of an animal may not be taken in a
given year.

[[Page 37691]]

\5\ This value represents the calculated PBR less the average annual estimate of ongoing anthropogenic mortalities (i.e., total annual human-caused M/
SI, which is presented in the SARs) (see Table 3). In parentheses, we provide the estimated maximum annual M/SI expressed as a percentage of this
value. For some stocks, a minimum population abundance value (and therefore PBR) is unavailable. In these cases, the proportion of estimated
population abundance represented by the Level B harassment total and/or the proportion of residual PBR represented by the estimated maximum annual M/
SI cannot be calculated.
\6\ See relevant SARs for more information regarding stock status and trends. Interannual increases may not be interpreted as evidence of a trend. Based
on the most recent abundance estimates, harbor seal stocks may have reached carrying capacity and appear stable. A time series of stock-specific
abundance estimates for harbor porpoise shows either increasing or stable estimates, but it is not statistically valid to infer a trend.
\7\ For western Steller sea lions, it is not appropriate to identify a single trend. Using data collected through 2015, there is strong evidence that
non-pup and pup counts increased at ~2 percent per year between 2000 and 2015. However, there are strong regional differences across the range in
Alaska, with positive trends east of Samalga Pass (~170[deg] W) in the Gulf of Alaska and eastern Bering Sea and negative trends to the west in the
Aleutian Islands. For more information, please see Muto et al. (2017).
\8\ No official abundance estimate is provided for these stocks; however, we use the best available information regarding population abundance for
comparison with the proposed total annual Level B harassment authorization. For the minke whale, surveys covering portions of the stock range provide
a partial abundance estimate of 2,020 (CV = 0.73) + 1,233 (CV = 0.34) whales. For the fin whale, we use the minimum abundance estimate provided for a
portion of the stock range (1,036 whales). Surveys in 2010-2012 provide an abundance estimate of 398 (CV = 0.12) + 577 (CV = 0.14) harbor porpoises in
southeast Alaska. However, the resulting total of 975 is not corrected for observer perception bias and porpoise availability at the surface, which is
particularly influential for estimates of porpoise abundance. Therefore, we apply a previously estimated correction factor of 2.96 (Hobbs and Waite,
2010) to this estimate for a provisional abundance estimate of 2,886. For the ringed seal, a partial abundance estimate (that does not account for
availability bias) of 170,000 seals is given. For more information, please see the relevant SARs.

Analysis--The majority of stocks that may potentially be taken by
M/SI (25 of 41) fall below the insignificance threshold (i.e., 10
percent of residual PBR), while an additional 11 stocks do not have
current PBR values and therefore are evaluated using other factors. We
first consider stocks expected to be affected only by behavioral
harassment and those stocks that fall below the insignificance
threshold. Next, we consider those stocks above the insignificance
threshold (i.e., the offshore stock of bottlenose dolphin, Risso's
dolphin, short-finned pilot whale, and the Pribilof Islands stock of
harbor seal) and those without PBR values (harbor seal stocks along the
Oregon and Washington coasts and in Washington inland waters; three
stocks of harbor porpoise; sperm whale; Pacific white-sided dolphin;
the Alaska stock of Dall's porpoise; and the ringed seal).
As described in greater depth previously (see ``Acoustic
Effects''), we do not believe that AFSC use of active acoustic sources
has the likely potential to cause any effect exceeding Level B
harassment of marine mammals. We have produced what we believe to be
precautionary estimates of potential incidents of Level B harassment.
There is a general lack of information related to the specific way that
these acoustic signals, which are generally highly directional and
transient, interact with the physical environment and to a meaningful
understanding of marine mammal perception of these signals and
occurrence in the areas where AFSC operates. The procedure for
producing these estimates, described in detail in ``Estimated Take Due
to Acoustic Harassment,'' represents NMFS's best effort towards
balancing the need to quantify the potential for occurrence of Level B
harassment with this general lack of information. The sources
considered here have moderate to high output frequencies, generally
short ping durations, and are typically focused (highly directional) to
serve their intended purpose of mapping specific objects, depths, or
environmental features. In addition, some of these sources can be
operated in different output modes (e.g., energy can be distributed
among multiple output beams) that may lessen the likelihood of
perception by and potential impacts on marine mammals in comparison
with the quantitative estimates that guide our proposed take
authorization. We also produced estimates of incidents of potential
Level B harassment due to disturbance of hauled-out pinnipeds that may
result from the physical presence of researchers; these estimates are
combined with the estimates of Level B harassment that may result from
use of active acoustic devices.
Here, we consider authorized Level B take less than five percent of
population abundance to be de minimis, while authorized Level B taking
between 5-15 percent is low. A moderate amount of authorized taking by
Level B harassment would be from 15-25 percent, and high above 25
percent. Of the 49 stocks that may be subject to Level B harassment,
the level of taking proposed for authorization would represent a de
minimis impact for 31 stocks and a low impact for an additional ten
stocks. We do not consider these impacts further for these 41 stocks.
The level of taking by Level B harassment would represent a moderate
impact on one additional stock, the South Kodiak stock of harbor seals;
and, therefore, we consider these potential impacts in conjunction with
the level of taking by M/SI. The annual taking by M/SI projected for
this stock equates to less than one percent of residual PBR; therefore
we do not consider this stock further. The total taking by Level B
harassment represents a high level of impact for three stocks (gray
whale and the offshore and AT1 stocks of killer whale). We discuss
these in further detail below. For an additional four stocks (sperm
whale and Alaska stocks of three beaked whale species), there is no
abundance estimate upon which to base a comparison. However, we note
that the anticipated number of incidents of take by Level B harassment
are very low (2-22 for these four stocks) and likely represent a de
minimis impact on these stocks.
As described previously, there is some minimal potential for
temporary effects to hearing for certain marine mammals, but most
effects would likely be limited to temporary behavioral disturbance.
Effects on individuals that are taken by Level B harassment will likely
be limited to reactions such as increased swimming speeds, increased
surfacing time, or decreased foraging (if such activity were
occurring), reactions that are considered to be of low severity (e.g.,
Ellison et al., 2012). Individuals may move away from the source if
disturbed; but, because the source is itself moving and because of the
directional nature of the sources considered here, there is unlikely to
be even temporary displacement from areas of significance and any
disturbance would be of short duration. Although there is no
information on which to base any distinction between incidents of
harassment and individuals harassed, the same factors, in conjunction
with the fact that AFSC survey effort is widely dispersed in space and
time, indicate that repeated exposures of the same individuals would be
very unlikely. For these reasons, we do not consider the proposed level
of take by acoustic disturbance to represent a significant additional
population stressor when considered in context with the proposed level
of take by M/SI for any species, including those for which no abundance
estimate is available.
There are no additional impacts other than Level B harassment
expected for the three stocks listed above for which Level B harassment
is expected to be at a relatively high level, i.e., the gray whale and
offshore and AT1 stocks of killer whale (Level B harassment incidents
equate to approximately 27, 28, and 29 percent of the stock abundances,
respectively). It should be noted that the AT1 stock of transient
killer whales has a critically low population abundance of seven
whales.

[[Page 37692]]

Although the estimate of take by Level B harassment is at 29 percent,
this represents only two estimated incidents of temporary and
insignificant behavioral disruption, which would not be expected to
affect annual rates of recruitment or survival for the stock. We do not
discuss these three stocks further.
Similarly, disturbance of pinnipeds on haul-outs by researchers
(expected for harbor seals and Steller sea lions in the GOARA and
BSAIRA) are expected to be infrequent and cause only a temporary
disturbance on the order of minutes. As noted previously, monitoring
results from other activities involving the disturbance of pinnipeds
and relevant studies of pinniped populations that experience more
regular vessel disturbance indicate that individually significant or
population level impacts are unlikely to occur. When considering the
individual animals likely affected by this disturbance, only a small
fraction of the estimated population abundance of the affected stocks
would be expected to experience the disturbance.
For Risso's dolphin, short-finned pilot whale, and the offshore
stock of bottlenose dolphin, maximum total potential M/SI due to NMFS'
fisheries research activity (SWFSC, NWFSC, and AFSC combined) is
approximately 11, 18, and 30 percent of residual PBR, respectively. For
example, PBR for Risso's dolphin is currently set at 46 and the annual
average of known ongoing anthropogenic M/SI is 3.7, yielding a residual
PBR value of 42.3. The maximum combined annual average M/SI incidental
to NMFS fisheries research activity is 4.6, or 10.9 percent of residual
PBR. The only known source of other anthropogenic mortality for these
species is in commercial fisheries. For the Risso's dolphin and
offshore stock of bottlenose dolphin, such take is considered to be
insignificant and approaching zero mortality and serious injury. This
is not the case for the short-finned pilot whale; however, the annual
take from fisheries (1.2) and from NMFS's fisheries research (0.6) are
both very low. There are no other factors that would lead us to believe
that take by M/SI of 18 percent of residual PBR would be problematic
for this species. Total potential M/SI due to NMFS' fisheries research
activity is approximately 11 percent of residual PBR for the Pribilof
Islands stock of harbor seals. However, there are no other known
sources of anthropogenic M/SI for this stock or other known significant
stressors; therefore, there is no indication that the take by M/SI of
11 percent of residual PBR would be problematic for this stock.
PBR is unknown for harbor seals on the Oregon and Washington coasts
and in Washington inland waters (comprised of the Hood Canal, southern
Puget Sound, and Washington northern inland waters stocks). The Hood
Canal, southern Puget Sound, and Washington northern inland waters
stocks were formerly a single inland waters stock. Both the Oregon/
Washington coast and Washington inland waters stocks of harbor seal
were considered to be stable following the most recent abundance
estimates (in 1999, stock abundances were estimated at 24,732 and
13,692, respectively). However, a Washington Department of Fish and
Wildlife expert (S. Jeffries) stated an unofficial abundance of 32,000
harbor seals in Washington (Mapes, 2013). Therefore, it is reasonable
to assume that at worst, the stocks have not declined since the last
abundance estimates. Ongoing anthropogenic mortality is estimated at
10.6 harbor seals per year for the coastal stock and 13.4 for inland
waters seals; therefore, we reasonably assume that the maximum
potential annual M/SI incidental to NMFS' fisheries research activities
(2.2 and 1.6, respectively) is a small fraction of any sustainable take
level that might be calculated for either stock.
As noted above, PBR is also undetermined for the sperm whale,
Pacific white-sided dolphin, three stocks of harbor porpoise, Alaska
stock of Dall's porpoise, and the ringed seal. We follow a similar
approach as for harbor seals (see above) in evaluating the significance
of the proposed M/SI by describing available information regarding
population abundance and other sources of anthropogenic M/SI.
Rice (1989) estimated that there were 930,000 sperm whales
in the North Pacific following the conclusion of commercial whaling.
However, this estimate included areas beyond the range of the U.S.
North Pacific stock of sperm whales. Kato and Miyashita (1998) produced
an estimate of 102,112 (CV = 0.155) sperm whales in the western North
Pacific. However, this estimate is considered to be positively biased,
and includes whales outside of Alaskan waters. Commercial fishing is
the only other source of ongoing anthropogenic M/SI, which is estimated
to be 3.7 whales per year. When considered in conjunction with the
maximum total annual M/SI anticipated as a result of NMFS fisheries
research activities (0.4), we expect that the resulting total annual M/
SI (4.1) is a small fraction of any sustainable take level that might
be calculated for the stock.
Historically, the minimum population estimate for the
Central North Pacific stock of Pacific white-sided dolphin was 26,880,
based on the sum of abundance estimates for four separate survey blocks
north of 45[deg] N from surveys conducted during 1987-1990, reported in
Buckland et al. (1993). This was considered a minimum estimate because
the abundance of animals in a fifth block, which straddled the boundary
of the two stocks for this species, was not included in the estimate
for the North Pacific stock. In addition, much of the potential habitat
for this stock was not surveyed between 1987 and 1990 (Muto et al.,
2017). Using this minimum abundance estimate in the PBR equation,
assuming the default 4 percent productivity rate and a recovery factor
of 0.5 (as recommended for stocks of unknown status), produces a PBR
value of 268.8. There are no other sources of anthropogenic M/SI for
this stock. The maximum total annual M/SI anticipated as a result of
NMFS fisheries research activities (1.6) would represent 0.6 percent of
residual PBR.
For the Alaska stock of Dall's porpoise, no current
estimate of minimum population abundance is available. However, an
abundance estimate of 83,400 was estimated on the basis of data
collected form 1987-1991 (Hobbs and Lerczak, 1993). Using this
population estimate and its associated CV of 0.097, the minimum
abundance would be 76,874. Using this estimate with the default
productivity rate and the recovery factor for stocks expected to be
within the OSP level (Buckland et al., 1993), a PBR value of 1,537.5
may be calculated. Accounting for ongoing M/SI due to commercial
fisheries, the maximum total annual M/SI anticipated as a result of
NMFS fisheries research activities (3.4) would represent 0.2 percent of
residual PBR.
For the Bering Sea stock of harbor porpoise, a minimum
abundance estimate of 40,039 was calculated by Hobbs and Waite (2010)
on the basis of a partial abundance estimate, derived from 1999 aerial
surveys of Bristol Bay. Although this estimate is formally considered
outdated for use in calculating PBR values, we use it here in the same
way as the Pacific white-sided dolphin and Dall's porpoise, addressed
above. As for the Pacific white-sided dolphin, we use the default
productivity rate and recovery factor for stocks of unknown status to
calculate a PBR value of 400.4. Accounting for minimal fisheries
mortality, the maximum total annual M/SI anticipated as a result of
NMFS fisheries research

[[Page 37693]]

activities (0.4) would represent 0.1 percent of residual PBR.
For the Gulf of Alaska stock of harbor porpoise, an
minimum abundance estimate of 25,987 was calculated by Hobbs and Waite
(2010) on the basis of an abundance estimate derived from 1998 aerial
surveys of the western Gulf of Alaska. Using the default productivity
rate and recovery factor for stocks of unknown status to calculate a
PBR value of 259.9. Accounting for relatively significant ongoing
fisheries mortality, the maximum total annual M/SI anticipated as a
result of NMFS fisheries research activities (0.8) would represent 0.4
percent of residual PBR.
A negatively biased minimum abundance estimate of 896 was
calculated for the southeast Alaska stock of harbor porpoise on the
basis of 2010-2012 aerial surveys (Muto et al., 2017). The estimate is
negatively biased because it does not account for observer perception
bias and porpoise availability at the surface. However, use of a widely
accepted correction factor (2.96) provides a minimum abundance estimate
of 2,652 and a corresponding PBR value of 26.5. This PBR value is less
than estimated annual ongoing mortality due to commercial fisheries
(34). However, the maximum total annual M/SI anticipated as a result of
NMFS fisheries research activities (0.2) represents a minimum potential
take of one animal over the 5-year period and would represent an
insignificant incremental addition to the total annual M/SI (0.6
percent).
Although NMFS does not provide a formal PBR value for the
ringed seal, Muto et al. (2017) provide a minimum abundance estimate of
170,000 seals in the U.S. sector of the Bering Sea. This is not
considered a reliable estimate for the stock because it does not
account for seals in the Chukchi and Beaufort Seas. However, as this is
a conservative minimum abundance estimate, we use the corresponding PBR
value of 5,100 given by Muto et al. (2017). Accounting for minimal
ongoing M/SI due to commercial fisheries, as well as ongoing
subsistence harvest of ringed seals, the maximum total annual M/SI
anticipated as a result of NMFS fisheries research activities (1.6)
would represent 0.04 percent of residual PBR.
In summary, our negligible impact analysis is founded on the
following factors: (1) The possibility of injury, serious injury, or
mortality from the use of active acoustic devices may reasonably be
considered discountable; (2) the anticipated incidents of Level B
harassment from the use of active acoustic devices and physical
disturbance of pinnipeds consist of, at worst, temporary and relatively
minor modifications in behavior; (3) the predicted number of incidents
of potential mortality are at insignificant levels for a majority of
affected stocks; (4) consideration of additional factors for Risso's
dolphin, short-finned pilot whale, the offshore stock of bottlenose
dolphin, and the Pribilof Isalnds stock of harbor seal do not reveal
cause for concern; (5) total maximum potential M/SI incidental to NMFS
fisheries research activity for southeast Alaska harbor porpoise,
considered in conjunction with other sources of ongoing mortality,
presents only a minimal incremental additional to total M/SI; (6)
available information regarding stocks for which no current PBR
estimate is available indicates that total maximum potential M/SI is
sustainable; and (7) the presumed efficacy of the planned mitigation
measures in reducing the effects of the specified activity to the level
of least practicable adverse impact. In combination, we believe that
these factors demonstrate that the specified activity will have only
short-term effects on individuals (resulting from Level B harassment)
and that the total level of taking will not impact rates of recruitment
or survival sufficiently to result in population-level impacts.
Based on the analysis contained herein of the likely effects of the
specified activity on marine mammals and their habitat, and taking into
consideration the implementation of the proposed monitoring and
mitigation measures, we preliminarily find that the total marine mammal
take from the proposed activities will have a negligible impact on the
affected marine mammal species or stocks.

Small Numbers

As noted above, only small numbers of incidental take may be
authorized under Section 101(a)(5)(A) of the MMPA for specified
activities. The MMPA does not define small numbers and so, in practice,
where estimated numbers are available, NMFS compares the number of
individuals taken to the most appropriate estimation of abundance of
the relevant species or stock in our determination of whether an
authorization is limited to small numbers of marine mammals.
Additionally, other qualitative factors may be considered in the
analysis, such as the temporal or spatial scale of the activities.
Please see Table 15 for information relating to this small numbers
analysis. The total amount of taking proposed for authorization is less
than five percent for a majority of stocks, and the total amount of
taking proposed for authorization is less than one-third of the stock
abundance for all stocks.
Based on the analysis contained herein of the proposed activity
(including the proposed mitigation and monitoring measures) and the
anticipated take of marine mammals, NMFS preliminarily finds that small
numbers of marine mammals will be taken relative to the population size
of the affected species or stocks.

Impact on Availability of Affected Species for Taking for Subsistence
Uses

In order to issue an LOA, NMFS must find that the specified
activity will not have an ``unmitigable adverse impact'' on the
subsistence uses of the affected marine mammal species or stocks by
Alaskan Natives. NMFS has defined ``unmitigable adverse impact'' in 50
CFR 216.103 as an impact resulting from the specified activity that:
(1) Is likely to reduce the availability of the species to a level
insufficient for a harvest to meet subsistence needs by:
(i) Causing the marine mammals to abandon or avoid hunting areas;
(ii) Directly displacing subsistence users; or
(iii) Placing physical barriers between the marine mammals and the
subsistence hunters; and
(2) Cannot be sufficiently mitigated by other measures to increase
the availability of marine mammals to allow subsistence needs to be
met.
As described in this preamble, the AFSC has requested authorization
of take incidental to fisheries research activities within Alaskan
waters. The proposed activities have the potential to result in M/SI of
marine mammals as a result of incidental interaction with research
gear, and have the potential to result in incidental Level B harassment
of marine mammals as a result of the use of active acoustic devices or
because of the physical presence of researchers at locations where
pinnipeds may be hauled out. These activities also have the potential
to result in impacts on the availability of marine mammals for
subsistence uses. The AFSC is aware of this potential and is committed
to implementing actions to avoid or to minimize any such effects to
Alaska Native subsistence communities. The AFSC addresses the potential
for their proposed research activities to impact subsistence uses on
the following factors:

[[Page 37694]]

Actions That May Cause Marine Mammals To Abandon or Avoid Hunting Areas

Some AFSC fisheries research efforts use high-frequency mapping and
fish-finding sonars to assess abundance and distribution of target
stocks of fish. The high frequency transient sound sources operated by
the AFSC are used for a wide variety of environmental and remote-object
sensing in the marine environment. These acoustic sources, which are
present on most AFSC fishery research vessels, include a variety of
single, dual, and multi-beam echosounders, sources used to determine
the orientation of trawl nets, and several current profilers. Some of
these acoustic sources are likely to be audible to some marine mammal
species. Among the marine mammals, most of these sources are unlikely
to be audible to whales and most pinnipeds, whereas they may be
detected by odontocete cetaceans (and particularly high frequency
specialists such as harbor porpoise). There is relatively little direct
information about behavioral responses of marine mammals, including the
odontocete cetaceans to these devices, but the responses that have been
measured in a variety of species to audible sounds suggest that the
most likely behavioral responses (if any) would be localized short-term
avoidance behavior (See ``Potential Effects of Specified Activities on
Marine Mammals and their Habitat''). As a general conclusion, while
some of the active acoustic sources used during AFSC fisheries research
surveys are likely to be detected by some marine species (particularly
phocid pinnipeds and odontocete cetaceans), the sound sources with
potential for disturbance would be temporary and transient in any
particular location as the research vessels move through an area. Any
changes in marine mammal behavior in response to the sound sources or
physical presence of the research vessel would likely involve temporary
avoidance behavior in the vicinity of the research vessel and would
return to normal after the vessel passed. Given the small number of
research vessels involved and their infrequent and inconsistent
presence in any given area from day to day, it is unlikely that the
proposed activity would cause animals to avoid any particular area.
Most AFSC fisheries research activities occur well away from land
and, in cases where they do approach land, include mitigation measures
to minimize the risk of disturbing pinnipeds hauled out on land. Any
incidental disturbance of pinnipeds on haul-outs would likely be
infrequent and result in temporary or short term changes in behavior.
This sporadic and temporary type of disturbance is not likely to result
in a change in use or abandonment of a known haul-out.
AFSC fisheries research activities generally are highly transient
and short term (e.g., several hours to a day in any one location) in
duration and take place well out to sea, far from coastal or ice pack
subsistence hunting activities. It is possible, albeit unlikely, for
these fisheries research sound sources to interact with migratory
species hunted for subsistence such that there could be short term
alterations in migratory pathways. However, as described in the AFSC
Communication Plan (Appendix B of AFSC's application), the AFSC will
work with subsistence users to identify important areas for marine
mammals and subsistence hunters early in the planning process as well
as in real time to identify the potential for overlap between migratory
pathways, key hunting regions and seasons, and proposed fisheries
research. This communication should lead to avoidance of any issues of
displacement of marine mammals and their prey.

Activities That May Directly Displace Subsistence Users

AFSC fisheries research primarily utilizes ocean-going ships
generally suited for offshore work. These vessels are not designed to
work in or near sea ice where much of the subsistence harvest of
pinnipeds occurs; thus research activities are most likely to occur
outside of periods when this type of hunting occurs. Due to the desire
to avoid disturbing pinnipeds hauled out on land, these ships largely
avoid nearshore routes that might otherwise put them in the path of
seal hunters.
Bowhead whale hunts may occur near sea ice in the spring or in open
water in the fall. AFSC fisheries research is only conducted during the
open water season in the Arctic so there is no risk of potential
interference with subsistence hunts in the spring. However, AFSC
fisheries research vessels may be present in whale hunting areas in the
fall and could potentially interfere with subsistence activities. The
communications plan is designed to minimize the risk of any such
interference by advance planning and communication between AFSC
scientists and subsistence hunting organizations (e.g., Alaska Eskimo
Whaling Commission) and real-time communication between AFSC research
vessels as they approach subsistence areas and nearby coastal community
contacts. The AFSC is committed to alter its research plans to address
any concerns about potential interference and to avoid any such
interference in the field.
AFSC fisheries research vessels make port calls in established
harbors and ports, thus reducing the chances for interaction with the
transit of hunters to and from coastal villages to nearby hunting
regions. As described in the Communication Plan provided as Appendix B
of AFSC's application, in those rare cases where a research vessel may
need to anchor offshore from a subsistence community, AFSC personnel
will, within the limits of maritime safety, direct the ship to a
predetermined location in coordination with the local subsistence
community so as to avoid interfering with those activities.

Activities That May Place Physical Barriers (Vessels and Gear) Between
the Marine Mammals and the Subsistence Hunters

The AFSC uses a variety of towed nets and sampling gear to conduct
its fisheries and ecosystem research. However, current operational
guidelines designed to reduce incidental catch of marine mammals
include measures that direct activities away from marine mammals near
the research vessel (move-on rule). These measures will reduce the
possibility for placing any barriers between subsistence hunters and
their marine mammal prey. As outlined in the Communication Plan, AFSC
will not deploy such research gear when subsistence hunters have been
visually observed in the area.
AFSC fisheries research will also strive to avoid working in any
areas when migrating species are present in the immediate vicinity. Per
the Communication Plan, the AFSC will coordinate both in advance and in
real time with known marine mammal hunting communities within the
immediate vicinity of research to avoid any interactions between
hunting activity and fisheries research vessels or gear.
The AFSC has provided a draft Communication Plan as Appendix B to
their application, and we invite comment on that document. The AFSC is
committed to conduct its proposed activities in ways that do not affect
the availability of marine mammals to subsistence hunters. The AFSC
will implement standard operational procedures and mitigation measures
to minimize direct impacts on marine mammals and will work with Alaska
Native organizations and coastal communities to develop effective

[[Page 37695]]

communication protocols to minimize the risk of potential interference
with subsistence activities. The AFSC will thus work to ensure that its
research activities do not negatively impact the availability of marine
mammals to Alaska Native subsistence users.
Based on the description of the specified activity, the measures
described to minimize adverse effects on the availability of marine
mammals for subsistence purposes, and the proposed mitigation and
monitoring measures, we have preliminarily determined that there will
not be an unmitigable adverse impact on subsistence uses from AFSC's
proposed activities.

Adaptive Management

The regulations governing the take of marine mammals incidental to
AFSC fisheries research survey operations would contain an adaptive
management component. The inclusion of an adaptive management component
will be both valuable and necessary within the context of five-year
regulations for activities that have been associated with marine mammal
mortality.
The reporting requirements associated with this proposed rule are
designed to provide OPR with monitoring data from the previous year to
allow consideration of whether any changes are appropriate. OPR and the
AFSC will meet annually to discuss the monitoring reports and current
science and whether mitigation or monitoring modifications are
appropriate. The use of adaptive management allows OPR to consider new
information from different sources to determine (with input from the
AFSC 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 reports, as required by MMPA authorizations; (2)
results from general marine mammal and sound research; and (3) any
information which reveals that marine mammals may have been taken in a
manner, extent, or number not authorized by these regulations or
subsequent LOAs.

Endangered Species Act (ESA)

There are multiple marine mammal species listed under the ESA with
confirmed or possible occurrence in the proposed specified geographical
regions (see Table 3). The proposed authorization of incidental take
pursuant to the AFSC's specified activity would not affect any
designated critical habitat. OPR has initiated consultation with NMFS's
Alaska Regional Office under section 7 of the ESA on the promulgation
of five-year regulations and the subsequent issuance of LOAs to AFSC
under section 101(a)(5)(A) of the MMPA. This consultation will be
concluded prior to issuing any final rule.

Request for Information

NMFS requests interested persons to submit comments, information,
and suggestions concerning the AFSC request and the proposed
regulations (see ADDRESSES). All comments will be reviewed and
evaluated as we prepare final rules and make final determinations on
whether to issue the requested authorizations. This notice and
referenced documents provide all environmental information relating to
our proposed action for public review.

Classification

Pursuant to the procedures established to implement Executive Order
12866, the Office of Management and Budget has determined that this
proposed rule is not significant.
Pursuant to section 605(b) of 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.
NMFS is the sole entity that would be subject to the requirements in
these proposed regulations, and NMFS is not a small governmental
jurisdiction, small organization, or small business, as defined by the
RFA. Because of this certification, a regulatory flexibility analysis
is not required and none has been prepared.
This proposed rule does not contain a collection-of-information
requirement subject to the provisions of the Paperwork Reduction Act
(PRA) because the applicant is a Federal agency. Notwithstanding any
other provision of law, no person is required to respond to nor shall a
person be subject to a penalty for failure to comply with a collection
of information subject to the requirements of the PRA unless that
collection of information displays a currently valid OMB control
number. These requirements have been approved by OMB under control
number 0648-0151 and include applications for regulations, subsequent
LOAs, and reports.

List of Subjects in 50 CFR Part 219

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

Dated: July 24, 2018.
Samuel D. Rauch III,
Deputy Assistant Administrator for Regulatory Programs, National Marine
Fisheries Service.

For reasons set forth in the preamble, 50 CFR part 219 is proposed
to be amended as follows:

PART 219--REGULATIONS GOVERNING THE TAKING AND IMPORTING OF MARINE
MAMMALS

0
1. The authority citation for part 219 continues to read as follows:

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

0
2. Add subpart F to part 219 to read as follows:
Subpart F--Taking Marine Mammals Incidental to Alaska Fisheries Science
Center Fisheries Research
Sec.
219.51 Specified activity and specified geographical region.
219.52 Effective dates.
219.53 Permissible methods of taking.
219.54 Prohibitions.
219.55 Mitigation requirements.
219.56 Requirements for monitoring and reporting.
219.57 Letters of Authorization.
219.58 Renewals and modifications of Letters of Authorization.
219.59-219.60 [Reserved]

Subpart F--Taking Marine Mammals Incidental to Alaska Fisheries
Science Center Fisheries Research

Sec. 219.51 Specified activity and specified geographical region.

(a) Regulations in this subpart apply only to the National Marine
Fisheries Service's (NMFS) Alaska Fisheries Science Center (AFSC) and
those persons it authorizes, including the International Pacific
Halibut Commission (IPHC) or funds to conduct activities on its behalf
for the taking of marine mammals that occurs in the areas outlined in
paragraph (b) of this section and that occurs incidental to research
survey program operations.
(b) The taking of marine mammals by AFSC may be authorized in a
Letter of Authorization (LOA) only if it occurs within the Gulf of
Alaska, Bering Sea and Aleutian Islands, Chukchi Sea and Beaufort Sea,
or is conducted by the IPHC in the Bering Sea and Aleutian

[[Page 37696]]

Islands, Gulf of Alaska, or off the U.S. West Coast.

Sec. 219.52 Effective dates.

Regulations in this subpart are effective from [EFFECTIVE DATE OF
FINAL RULE] through [DATE 5 YEARS AFTER EFFECTIVE DATE OF FINAL RULE].

Sec. 219.53 Permissible methods of taking.

Under LOAs issued pursuant to Sec. 216.106 of this chapter and
Sec. 219.57, the Holder of the LOA (hereinafter ``AFSC'') may
incidentally, but not intentionally, take marine mammals within the
area described in Sec. 219.51(b) by Level B harassment associated with
use of active acoustic systems and physical or visual disturbance of
hauled-out pinnipeds and by Level A harassment, serious injury, or
mortality associated with use of hook and line gear, trawl gear, and
gillnet gear, provided the activity is in compliance with all terms,
conditions, and requirements of the regulations in this subpart and the
appropriate LOA.

Sec. 219.54 Prohibitions.

Notwithstanding takings contemplated in Sec. 219.51 and authorized
by a LOA issued under Sec. 216.106 of this chapter and Sec. 219.57,
no person in connection with the activities described in Sec. 219.51
may:
(a) Violate, or fail to comply with, the terms, conditions, and
requirements of this subpart or a LOA issued under Sec. 216.106 of
this chapter and Sec. 219.57;
(b) Take any marine mammal not specified in such LOA;
(c) Take any marine mammal specified in such LOA in any manner
other than as specified;
(d) Take a marine mammal specified in such LOA if NMFS determines
such taking results in more than a negligible impact on the species or
stocks of such marine mammal; or
(e) Take a marine mammal specified in such LOA if NMFS determines
such taking results in an unmitigable adverse impact on the species or
stock of such marine mammal for taking for subsistence uses.

Sec. 219.55 Mitigation requirements.

When conducting the activities identified in Sec. 219.51(a), the
mitigation measures contained in any LOA issued under Sec. 216.106 of
this chapter and Sec. 219.57 must be implemented. These mitigation
measures shall include but are not limited to:
(a) General conditions: (1) AFSC shall convey relevant mitigation,
monitoring, and reporting requirements to the IPHC, as indicated in the
following subparts.
(2) AFSC shall take all necessary measures to coordinate and
communicate in advance of each specific survey with the National
Oceanic and Atmospheric Administration's (NOAA) Office of Marine and
Aviation Operations (OMAO) or other relevant parties on non-NOAA
platforms to ensure that all mitigation measures and monitoring
requirements described herein, as well as the specific manner of
implementation and relevant event-contingent decision-making processes,
are clearly understood and agreed upon. AFSC shall convey this
requirement to IPHC.
(2) AFSC shall coordinate and conduct briefings at the outset of
each survey and as necessary between ship's crew (Commanding Officer/
master or designee(s), as appropriate) and scientific party in order to
explain responsibilities, communication procedures, marine mammal
monitoring protocol, and operational procedures. AFSC shall convey this
requirement to IPHC.
(3) AFSC shall coordinate as necessary on a daily basis during
survey cruises with OMAO personnel or other relevant personnel on non-
NOAA platforms to ensure that requirements, procedures, and decision-
making processes are understood and properly implemented. AFSC shall
convey this requirement to IPHC.
(4) When deploying any type of sampling gear at sea, AFSC shall at
all times monitor for any unusual circumstances that may arise at a
sampling site and use best professional judgment to avoid any potential
risks to marine mammals during use of all research equipment. AFSC
shall convey this requirement to IPHC.
(5) AFSC shall implement handling and/or disentanglement protocols
as specified in the guidance that shall be provided to AFSC survey
personnel. AFSC shall convey this requirement to IPHC.
(6) AFSC shall not approach within 1 km of locations where marine
mammals are aggregated, including pinniped rookeries and haul-outs.
(7) AFSC shall adhere to a final Communication Plan. In summary and
in accordance with the Plan, AFSC shall:
(i) Notify and provide potentially affected Alaska Native
subsistence communities with the Communication Plan through a series of
mailings, direct contacts, and planned meetings throughout the regions
where AFSC fisheries research is expected to occur;
(ii) Meet with potentially affected subsistence communities to
discuss planned activities and to resolve potential conflicts regarding
any aspects of either the fisheries research operations or the
Communication Plan;
(iii) Develop field operations plans as necessary, which shall
address how researchers will consult and maintain communication with
contacts in the potentially affected subsistence communities when in
the field, including a list of local contacts and contact mechanisms,
and which shall describe operational procedures and actions planned to
avoid or minimize the risk of interactions between AFSC fisheries
research and local subsistence activities;
(iv) Schedule post-season informational sessions with subsistence
contacts from the study areas to brief them on the outcome of the AFSC
fisheries research and to assess performance of the Communication Plan
and individual field operations or cruise plans in working to minimize
effects to subsistence activities; and
(v) Evaluate overall effectiveness of the Communications Plan in
year four of any LOA issued pursuant to Sec. 216.106 of this chapter
and Sec. 219.57.
(b) Trawl survey protocols: (1) AFSC shall conduct trawl operations
as soon as is practicable upon arrival at the sampling station.
(2) AFSC shall initiate marine mammal watches (visual observation)
at least 15 minutes prior to beginning of net deployment, but shall
also conduct monitoring during any pre-set activities including
trackline reconnaissance, CTD casts, and plankton or bongo net hauls.
Marine mammal watches shall be conducted by scanning the surrounding
waters with the naked eye and rangefinding binoculars (or monocular).
During nighttime operations, visual observation shall be conducted
using the naked eye and available vessel lighting.
(3) AFSC shall implement the move-on rule mitigation protocol, as
described in this paragraph. If one or more marine mammals are observed
and are considered at risk of interacting with the vessel or research
gear, or appear to be approaching the vessel and are considered at risk
of interaction, AFSC shall either remain onsite or move on to another
sampling location. If remaining onsite, the set shall be delayed. If
the animals depart or appear to no longer be at risk of interacting
with the vessel or gear, a further observation period shall be
conducted. If no further observations are made or the animals still do
not appear to be at risk of interaction, then the set may be made. If
the vessel is moved to a different section of the sampling area, the
move-on rule

[[Page 37697]]

mitigation protocol would begin anew. If, after moving on, marine
mammals remain at risk of interaction, the AFSC shall move again or
skip the station. Marine mammals that are sighted shall be monitored to
determine their position and movement in relation to the vessel to
determine whether the move-on rule mitigation protocol should be
implemented. AFSC may use best professional judgment in making these
decisions.
(4) AFSC shall maintain visual monitoring effort during the entire
period of time that trawl gear is in the water (i.e., throughout gear
deployment, fishing, and retrieval). If marine mammals are sighted
before the gear is fully removed from the water, AFSC shall take the
most appropriate action to avoid marine mammal interaction. AFSC may
use best professional judgment in making this decision.
(5) If trawling operations have been suspended because of the
presence of marine mammals, AFSC may resume trawl operations when
practicable only when the animals are believed to have departed the
area. AFSC may use best professional judgment in making this
determination.
(6) AFSC shall implement standard survey protocols to minimize
potential for marine mammal interactions, including maximum tow
durations at target depth and maximum tow distance, and shall carefully
empty the trawl as quickly as possible upon retrieval.
(7) Whenever surface trawl nets are used in southeast Alaska, AFSC
must install and use acoustic deterrent devices, with two pairs of the
devices installed near the net opening. AFSC must ensure that the
devices are operating properly before deploying the net.
(c) Longline survey protocols: (1) AFSC shall deploy longline gear
as soon as is practicable upon arrival at the sampling station. AFSC
shall convey this requirement to IPHC.
(2) AFSC shall initiate marine mammal watches (visual observation)
no less than 30 minutes (or for the duration of transit between set
locations, if shorter than 30 minutes) prior to both deployment and
retrieval of longline gear. Marine mammal watches shall be conducted by
scanning the surrounding waters with the naked eye and rangefinding
binoculars (or monocular). During nighttime operations, visual
observation shall be conducted using the naked eye and available vessel
lighting. AFSC shall convey this requirement to IPHC.
(3) AFSC shall implement the move-on rule mitigation protocol, as
described in this paragraph. If one or more marine mammals are observed
in the vicinity of the planned location before gear deployment, and are
considered at risk of interacting with the vessel or research gear, or
appear to be approaching the vessel and are considered at risk of
interaction, AFSC shall either remain onsite or move on to another
sampling location. If remaining onsite, the set shall be delayed. If
the animals depart or appear to no longer be at risk of interacting
with the vessel or gear, a further observation period shall be
conducted. If no further observations are made or the animals still do
not appear to be at risk of interaction, then the set may be made. If
the vessel is moved to a different section of the sampling area, the
move-on rule mitigation protocol would begin anew. If, after moving on,
marine mammals remain at risk of interaction, the AFSC shall move again
or skip the station. Marine mammals that are sighted shall be monitored
to determine their position and movement in relation to the vessel to
determine whether the move-on rule mitigation protocol should be
implemented. AFSC may use best professional judgment in making these
decisions. AFSC shall convey this requirement to IPHC.
(4) AFSC shall maintain visual monitoring effort during the entire
period of gear deployment and retrieval. If marine mammals are sighted
before the gear is fully deployed or retrieved, AFSC shall take the
most appropriate action to avoid marine mammal interaction. AFSC may
use best professional judgment in making this decision. AFSC shall
convey this requirement to IPHC.
(5) If deployment or retrieval operations have been suspended
because of the presence of marine mammals, AFSC may resume such
operations when practicable only when the animals are believed to have
departed the area. AFSC may use best professional judgment in making
this decision. AFSC shall convey this requirement to IPHC.
(d) Gillnet survey protocols: (1) AFSC shall conduct gillnet
operations as soon as is practicable upon arrival at the sampling
station.
(2) AFSC shall conduct marine mammal watches (visual observation)
prior to beginning of net deployment. Marine mammal watches shall be
conducted by scanning the surrounding waters with the naked eye and
rangefinding binoculars (or monocular).
(3) AFSC shall implement the move-on rule mitigation protocol. If
one or more marine mammals are observed in the vicinity of the planned
location before gear deployment, and are considered at risk of
interacting with research gear, AFSC shall either remain onsite or move
on to another sampling location. If remaining onsite, the set shall be
delayed. If the animals depart or appear to no longer be at risk of
interacting with the gear, a further observation period shall be
conducted. If no further observations are made or the animals still do
not appear to be at risk of interaction, then the set may be made. If
the vessel is moved to a different area, the move-on rule mitigation
protocol would begin anew. If, after moving on, marine mammals remain
at risk of interaction, the AFSC shall move again or skip the station.
Marine mammals that are sighted shall be monitored to determine their
position and movement in relation to the vessel to determine whether
the move-on rule mitigation protocol should be implemented. AFSC may
use best professional judgment in making these decisions.
(4) AFSC shall maintain visual monitoring effort during the entire
period of time that gillnet gear is in the water (i.e., throughout gear
deployment, fishing, and retrieval). If marine mammals are sighted
before the gear is fully removed from the water, and appear to be at
risk of interaction with the gear, AFSC shall pull the gear
immediately. AFSC may use best professional judgment in making this
decision.
(5) If gillnet operations have been suspended because of the
presence of marine mammals, AFSC may resume gillnet operations when
practicable only when the animals are believed to have departed the
area. AFSC may use best professional judgment in making this
determination.
(6) AFSC must install and use acoustic deterrent devices whenever
gillnets are used. AFSC must ensure that the devices are operating
properly before deploying the net.

Sec. 219.56 Requirements for monitoring and reporting.

(a) AFSC shall designate a compliance coordinator who shall be
responsible for ensuring compliance with all requirements of any LOA
issued pursuant to Sec. 216.106 of this chapter and Sec. 219.57 and
for preparing for any subsequent request(s) for incidental take
authorization. AFSC shall convey this requirement to IPHC.
(b) Visual monitoring program: (1) Marine mammal visual monitoring
shall occur prior to deployment of trawl, longline, and gillnet gear,
respectively; throughout deployment of gear and active fishing of
research gears (not including longline soak time); prior to

[[Page 37698]]

retrieval of longline gear; and throughout retrieval of all research
gear. AFSC shall convey this requirement to IPHC.
(2) Marine mammal watches shall be conducted by watch-standers
(those navigating the vessel and/or other crew) at all times when the
vessel is being operated. AFSC shall convey this requirement to IPHC.
(c) Training: (1) AFSC must conduct annual training for all chief
scientists and other personnel who may be responsible for conducting
dedicated marine mammal visual observations to explain mitigation
measures and monitoring and reporting requirements, mitigation and
monitoring protocols, marine mammal identification, completion of
datasheets, and use of equipment. AFSC may determine the agenda for
these trainings.
(2) AFSC shall also dedicate a portion of training to discussion of
best professional judgment, including use in any incidents of marine
mammal interaction and instructive examples where use of best
professional judgment was determined to be successful or unsuccessful.
(3) AFSC shall convey these training requirements to IPHC.
(d) Handling procedures and data collection: (1) AFSC must develop
and implement standardized marine mammal handling, disentanglement, and
data collection procedures. These standard procedures will be subject
to approval by NMFS's Office of Protected Resources (OPR). AFSC shall
convey these procedures to IPHC.
(2) When practicable, for any marine mammal interaction involving
the release of a live animal, AFSC shall collect necessary data to
facilitate a serious injury determination. AFSC shall convey this
requirement to IPHC.
(3) AFSC shall provide its relevant personnel with standard
guidance and training regarding handling of marine mammals, including
how to identify different species, bring an individual aboard a vessel,
assess the level of consciousness, remove fishing gear, return an
individual to water, and log activities pertaining to the interaction.
AFSC shall convey this requirement to IPHC.
(4) AFSC shall record such data on standardized forms, which will
be subject to approval by OPR. AFSC shall also answer a standard series
of supplemental questions regarding the details of any marine mammal
interaction. AFSC shall convey this requirement to IPHC.
(e) Reporting: (1) AFSC shall report all incidents of marine mammal
interaction to NMFS's Protected Species Incidental Take database,
including those resulting from IPHC activities, within 48 hours of
occurrence and shall provide supplemental information to OPR upon
request. Information related to marine mammal interaction (animal
captured or entangled in research gear) must include details of survey
effort, full descriptions of any observations of the animals, the
context (vessel and conditions), decisions made, and rationale for
decisions made in vessel and gear handling.
(2) Annual reporting: (i) AFSC shall submit an annual summary
report to OPR not later than ninety days following the end of a given
year. AFSC shall provide a final report within thirty days following
resolution of comments on the draft report.
(ii) These reports shall contain, at minimum, the following:
(A) Annual line-kilometers surveyed during which the EK60, ME70,
ES60, 7111 (or equivalent sources) were predominant and associated pro-
rated estimates of actual take;
(B) Summary information regarding use of all longline, gillnet, and
trawl gear, including number of sets, tows, etc., specific to each
gear;
(C) Accounts of all incidents of significant marine mammal
interactions, including circumstances of the event and descriptions of
any mitigation procedures implemented or not implemented and why;
(D) A written evaluation of the effectiveness of AFSC mitigation
strategies in reducing the number of marine mammal interactions with
survey gear, including best professional judgment and suggestions for
changes to the mitigation strategies, if any;
(E) Final outcome of serious injury determinations for all
incidents of marine mammal interactions where the animal(s) were
released alive; and
(F) A summary of all relevant training provided by AFSC and any
coordination with NMFS' Alaska Regional Office.
(3) AFSC shall convey these reporting requirements to IPHC and
shall provide IPHC reports to OPR subject to the same schedule.
(f) Reporting of injured or dead marine mammals:
(1) In the unanticipated event that the activity defined in Sec.
219.51(a) of this chapter clearly causes the take of a marine mammal in
a prohibited manner, AFSC personnel engaged in the research activity
shall immediately cease such activity until such time as an appropriate
decision regarding activity continuation can be made by the AFSC
Director (or designee). The incident must be reported immediately to
OPR and the Alaska Regional Stranding Coordinator, NMFS. OPR will
review the circumstances of the prohibited take and work with AFSC to
determine what measures are necessary to minimize the likelihood of
further prohibited take and ensure MMPA compliance. The immediate
decision made by AFSC regarding continuation of the specified activity
is subject to OPR concurrence. The report must include the following
information:
(i) Time, date, and location (latitude/longitude) of the incident;
(ii) Description of the incident;
(iii) Environmental conditions (e.g., wind speed and direction,
Beaufort sea state, cloud cover, visibility);
(iv) Description of all marine mammal observations in the 24 hours
preceding the incident;
(v) Species identification or description of the animal(s)
involved;
(vi) Status of all sound source use in the 24 hours preceding the
incident;
(vii) Water depth;
(viii) Fate of the animal(s); and
(ix) Photographs or video footage of the animal(s).
(2) In the event that AFSC discovers an injured or dead marine
mammal and determines that the cause of the injury or death is unknown
and the death is relatively recent (e.g., in less than a moderate state
of decomposition), AFSC shall immediately report the incident to OPR
and the Alaska Regional Stranding Coordinator, NMFS. The report must
include the information identified in paragraph (f)(1) of this section.
Activities may continue while OPR reviews the circumstances of the
incident. OPR will work with AFSC to determine whether additional
mitigation measures or modifications to the activities are appropriate.
(3) In the event that AFSC discovers an injured or dead marine
mammal and determines that the injury or death is not associated with
or related to the activities defined in Sec. 219.51(a) of this chapter
(e.g., previously wounded animal, carcass with moderate to advanced
decomposition, scavenger damage), AFSC shall report the incident to OPR
and the Alaska Regional Stranding Coordinator, NMFS, within 24 hours of
the discovery. AFSC shall provide photographs or video footage or other
documentation of the stranded animal sighting to OPR.
(4) AFSC shall convey these requirements to IPHC.

Sec. 219.57 Letters of Authorization.

(a) To incidentally take marine mammals pursuant to these
regulations, AFSC must apply for and obtain an LOA.
(b) An LOA, unless suspended or revoked, may be effective for a
period of

[[Page 37699]]

time not to exceed the expiration date of these regulations.
(c) If an LOA expires prior to the expiration date of these
regulations, AFSC may apply for and obtain a renewal of the LOA.
(d) In the event of projected changes to the activity or to
mitigation and monitoring measures required by an LOA, AFSC must apply
for and obtain a modification of the LOA as described in Sec. 219.58.
(e) The LOA shall set forth:
(1) Permissible methods of incidental taking;
(2) Means of effecting the least practicable adverse impact (i.e.,
mitigation) on the species, its habitat, and on the availability of the
species for subsistence uses; and
(3) Requirements for monitoring and reporting.
(f) Issuance of the LOA shall be based on a determination that the
level of taking will be consistent with the findings made for the total
taking allowable under these regulations.
(g) Notice of issuance or denial of an LOA shall be published in
the Federal Register within thirty days of a determination.

Sec. 219.58 Renewals and modifications of Letters of Authorization.

(a) An LOA issued under Sec. 216.106 of this chapter and Sec.
219.57 for the activity identified in Sec. 219.51(a) shall be renewed
or modified upon request by 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 in paragraph (c)(1)
of this section), and
(2) OPR determines that the mitigation, monitoring, and reporting
measures required by the previous LOA under these regulations were
implemented.
(b) For an 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 in paragraph (c)(1) of this section) 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), OPR may publish a notice of proposed LOA in the
Federal Register, including the associated analysis of the change, and
solicit public comment before issuing the LOA.
(c) An LOA issued under Sec. 216.106 of this chapter and Sec.
219.57 for the activity identified in Sec. 219.51(a) may be modified
by OPR under the following circumstances:
(1) Adaptive Management--OPR may modify (including augment) the
existing mitigation, monitoring, or reporting measures (after
consulting with AFSC regarding the practicability of the modifications)
if doing so creates a reasonable likelihood of more effectively
accomplishing the goals of the mitigation and monitoring set forth in
the preamble for these regulations.
(i) Possible sources of data that could contribute to the decision
to modify the mitigation, monitoring, or reporting measures in an LOA:
(A) Results from AFSC's monitoring from the previous year(s).
(B) Results from other marine mammal and/or sound research or
studies.
(C) Any information that reveals marine mammals may have been taken
in a manner, extent or number not authorized by these regulations or
subsequent LOAs.
(ii) If, through adaptive management, the modifications to the
mitigation, monitoring, or reporting measures are substantial, OPR will
publish a notice of proposed LOA in the Federal Register and solicit
public comment.
(2) Emergencies--If OPR determines that an emergency exists that
poses a significant risk to the well-being of the species or stocks of
marine mammals specified in LOAs issued pursuant to Sec. 216.106 of
this chapter and Sec. 219.57, an LOA may be modified without prior
notice or opportunity for public comment. Notice would be published in
the Federal Register within thirty days of the action.

Sec. Sec. 219.59-219.60 [Reserved]

[FR Doc. 2018-16114 Filed 7-31-18; 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.
Dates		Comments and information must be received no later than August 31, 2018.
Contact		Ben Laws, Office of Protected Resources, NMFS, (301) 427-8401.
FR Citation		83 FR 37638
RIN Number		0648-BG64
CFR Associated		Exports; Fish; Imports; Indians; Labeling; Marine Mammals; Penalties; Reporting and Recordkeeping Requirements; Seafood and Transportation

83 FR 37638 - Taking and Importing Marine Mammals; Taking Marine Mammals Incidental to Alaska Fisheries Science Center Fisheries Research

DEPARTMENT OF COMMERCENational Oceanic and Atmospheric Administration

Federal Register Volume 83, Issue 148 (August 1, 2018)

DEPARTMENT OF COMMERCE
National Oceanic and Atmospheric Administration