[Federal Register Volume 82, Number 186 (Wednesday, September 27, 2017)]
[Notices]
[Pages 45116-45156]
From the Federal Register Online via the Government Publishing Office [www.gpo.gov]
[FR Doc No: 2017-20696]
[[Page 45115]]
Vol. 82
Wednesday,
No. 186
September 27, 2017
Part II
Department of Commerce
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National Oceanic and Atmospheric Administration
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Takes of Marine Mammals Incidental to Specified Activities; Taking
Marine Mammals Incidental to a Marine Geophysical Survey in the
Southwest Pacific Ocean, 2017/2018; Notice
Federal Register / Vol. 82 , No. 186 / Wednesday, September 27, 2017
/ Notices
[[Page 45116]]
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DEPARTMENT OF COMMERCE
National Oceanic and Atmospheric Administration
RIN 0648-XF456
Takes of Marine Mammals Incidental to Specified Activities;
Taking Marine Mammals Incidental to a Marine Geophysical Survey in the
Southwest Pacific Ocean, 2017/2018
AGENCY: National Marine Fisheries Service (NMFS), National Oceanic and
Atmospheric Administration (NOAA), Commerce.
ACTION: Notice; proposed incidental harassment authorization; request
for comments.
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SUMMARY: NMFS has received a request from Lamont-Doherty Earth
Observatory (L-DEO) for authorization to take marine mammals incidental
to a WHEN OU marine geophysical survey in the southwest Pacific Ocean.
Pursuant to the Marine Mammal Protection Act (MMPA), NMFS is requesting
comments on its proposal to issue an incidental harassment
authorization (IHA) to incidentally take marine mammals during the
specified activities. 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 notice of
our final decision.
DATES: Comments and information must be received no later than October
26, 2017.
ADDRESSES: Comments should be addressed to Jolie Harrison, Chief,
Permits and Conservation Division, Office of Protected Resources,
National Marine Fisheries Service. Physical comments should be sent to
1315 East-West Highway, Silver Spring, MD 20910 and electronic comments
should be sent to [email protected].
Instructions: NMFS is not responsible for comments sent by any
other method, to any other address or individual, or received after the
end of the comment period. Comments received electronically, including
all attachments, must not exceed a 25-megabyte file size. Attachments
to electronic comments will be accepted in Microsoft Word or Excel or
Adobe PDF file formats only. All comments received are a part of the
public record and will generally be posted online at www.nmfs.noaa.gov/pr/permits/incidental/research.htm without change. All personal
identifying information (e.g., name, address) voluntarily submitted by
the commenter may be publicly accessible. Do not submit confidential
business information or otherwise sensitive or protected information.
FOR FURTHER INFORMATION CONTACT: Jordan Carduner, Office of Protected
Resources, NMFS, (301) 427-8401. Electronic copies of the application
and 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.
SUPPLEMENTARY INFORMATION:
Background
Sections 101(a)(5)(A) and (D) of the MMPA (16 U.S.C. 1361 et seq.)
direct 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 and either regulations are issued or, if
the taking is limited to harassment, a notice of a proposed
authorization is provided to the public for review.
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.
The MMPA states that the term ``take'' means to harass, hunt,
capture, or 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 review our proposed action (i.e., the issuance of an
incidental harassment authorization) with respect to potential impacts
on the human environment. Accordingly, NMFS is preparing an
Environmental Assessment (EA) to consider the environmental impacts
associated with the issuance of the proposed IHA. NMFS' EA is available
at www.nmfs.noaa.gov/pr/permits/incidental/research.htm. We will review
all comments submitted in response to this notice prior to concluding
our NEPA process or making a final decision on the IHA request.
Summary of Request
On May 17, 2017, NMFS received a request from the L-DEO for an IHA
to take marine mammals incidental to conducting a marine geophysical
survey in the southwest Pacific Ocean. On September 13, 2017, we deemed
L-DEO's application for authorization to be adequate and complete. L-
DEO's request is for take of a small number of 38 species of marine
mammals by Level B harassment and Level A harassment. Neither L-DEO nor
NMFS expects mortality to result from this activity, and, therefore, an
IHA is appropriate. The planned activity is not expected to exceed one
year, hence, we do not expect subsequent MMPA incidental harassment
authorizations would be issued for this particular activity.
Description of Proposed Activity
Overview
Researchers from California State Polytechnic University,
California Institute of Technology, Pennsylvania State University,
University Southern California, University of Southern Mississippi
(USM), University of Hawaii at Manoa, University of Texas, and
University of Wisconsin Madison, with funding from the U.S. National
Science Foundation, propose to conduct three high-energy seismic
surveys from the research vessel (R/V) Marcus G. Langseth (Langseth) in
the waters of New Zealand in the southwest Pacific Ocean in 2017/2018.
The NSF-owned Langseth is operated by L-DEO. One proposed survey would
occur east of North Island and would use an 18-airgun towed array with
a total discharge volume of ~3300 cubic inches (in\3\). Two other
proposed seismic surveys (one off the east coast of North Island and
one south of South Island)
[[Page 45117]]
would use a 36-airgun towed array with a discharge volume of ~6600
in\3\. The surveys would take place in water depths from ~50 to >5,000
m.
Dates and Duration
The North Island two-dimensional (2-D) survey would consist of
approximately 35 days of seismic operations plus approximately 2 days
of transit and towed equipment deployment/retrieval. The Langseth would
depart Auckland on approximately October 26, 2017 and arrive in
Wellington on December 1, 2017. The North Island three-dimensional (3-
D) survey is proposed for approximately January 5, 2018-February 8,
2018 and would consist of approximately 33 days of seismic operations
plus approximately 2 days of transit and towed equipment deployment/
retrieval. The Langseth would leave and return to port in Napier. The
South Island 2-D survey is proposed for approximately February 15,
2018-March 15, 2018 and would consist of approximately 22 days of
seismic operations, approximately 3 days of transit, and approximately
7 days of ocean bottom seismometer (OBS) deployment/retrieval.
Specific Geographic Region
The proposed surveys would occur within the Exclusive Economic Zone
(EEZ) and territorial sea of New Zealand. The proposed North Island 2-D
survey would occur within ~37-43[deg] S. between 180[deg] E. and the
east coast of North Island along the Hikurangi margin. The proposed
North Island 3-D survey would occur over a 15 x 60 kilometer (km) area
offshore at the Hikurangi trench and forearc off North Island within
~38-39.5[deg] S., ~178-179.5[deg] E. The proposed South Island 2-D
survey would occur along the Puysegur margin off South Island within
~163-168[deg] E. between 50[deg] S. and the south coast of South
Island. Please see Figure 1 and Figure 2 in L-DEO's IHA application for
maps depicting the specified geographic region of the proposed surveys.
Detailed Description of Specific Activity
The proposed study consists of three seismic surveys off the coast
of New Zealand in the southwest Pacific Ocean. The proposed surveys
include: (1) A 2-D survey along the Hikurangi margin off the east coast
of North Island; (2) a deep penetrating 3-D seismic reflection
acquisition over a 15 x 60 km area offshore at the Hikurangi trench and
forearc off the east coast of North Island; and (3) a 2-D survey along
the Puysegur margin off the south coast of South Island. Water depths
in the proposed survey areas range from ~50 to >5000 m. The proposed
surveys would be conducted within both the territorial sea of New
Zealand (from 0-12 nautical miles (nm) from shore) and the EEZ of New
Zealand (from 12 to 200 nm from shore). All planned geophysical data
acquisition activities would be conducted by L-DEO with onboard
assistance by the scientists who have proposed the studies. The vessel
would be self-contained, and the crew would live aboard the vessel.
Survey protocols generally involve a predetermined set of survey,
or track lines. The seismic acquisition vessel (source vessel) travels
down a linear track for some distance until a line of data is acquired,
then turns and acquires data on a different track. Representative
survey tracklines are shown in Figures 1 and 2 in L-DEO's IHA; however,
some deviation in actual track lines could be necessary for reasons
such as science drivers, poor data quality, inclement weather, or
mechanical issues with the research vessel and/or equipment. The
proposed surveys would entail a total of approximately 13,299 km of
track lines.
During the two 2-D surveys, the Langseth would tow a full array,
consisting of four strings with 36 airguns (plus 4 spares) and a total
volume of approximately 6,600 in\3\. During the North Island 3-D
survey, the Langseth would tow two separate 18-airgun arrays that would
fire alternately; each array would have a total discharge volume of
approximately 3,300 in\3\. Specifications of the airgun arrays,
trackline distances, and water depths of each of the three proposed
surveys are shown in Table 1. Descriptions of the three proposed
surveys are provided below. More detailed descriptions of the three
proposed surveys are provided in the IHA application (LGL, 2017).
Table 1--Specifications of Airgun Arrays, Trackline Distances, and Water Depths Associated With Three Proposed R/
V Langseth Surveys Off New Zealand
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North Island 2-D survey North Island 3-D survey South Island 2-D survey
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Airgun array configuration and total 36 airguns, four two separate 18-airgun 36 airguns, four
volume. strings, total volume arrays that would fire strings, total volume
of ~6,600 in\3\. alternately; each of ~6,600 in\3\.
array would have a
total discharge volume
of ~3,300 in\3\.
Tow depth of arrays.................. 9 m.................... 9 m.................... 9 m.
Shot point intervals................. 37.5 m................. 37.5 m................. 50 m.
Source velocity (tow speed).......... 4.3 knots.............. 4.5 knots.............. 4.5 knots.
Water depths......................... 8%, 23%, and 69% of 0%, 42%, and 58% of 1%, 17%, and 82% of
line km would take line km would take line km would take
place in shallow (<100 place in shallow, place in shallow,
m), intermediate (100- intermediate, and deep intermediate, and deep
1000 m), and deep water, respectively. water, respectively.
water (>1000 m),
respectively.
Approximate trackline distance....... 5,398 km............... 3,025 km............... 4,876 km.
Percentage of survey tracklines Approximately 9 percent Approximately 1 percent Approximately 6
proposed in New Zealand Territorial percent.
Waters.
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North Island 2-D Survey
During the proposed North Island 2-D survey, approximately 5,398 km
of track lines would be surveyed, spanning an area off eastern North
Island from the south coast to the Bay of Plenty. Approximately 9
percent of the proposed North Island 2-D survey would occur within New
Zealand's territorial sea. The main goal of the proposed North Island
2-D survey is to collect seismic data to create images of the plate
boundary fault zone and to show other faults and folding of the upper
New Zealand plate and the underlying Pacific plate. The data would
improve scientific understanding of why the different parts of the same
[[Page 45118]]
plate boundary are behaving so differently to produce slow slip events
and large stick-slip earthquakes. A better understanding of what causes
the differences may help New Zealand government agencies in their
efforts to mitigate danger posed by earthquakes in this area.
To achieve the project goals of the North Island 2-D survey, the
principal investigators (PIs) and co-PIs propose to use multi-channel
seismic (MCS) reflection surveys and seismic refraction data recorded
by OBSs to characterize the incoming Hikurangi Plateau and the seaward
portion of the accretionary prism, and document subducted sediment
variations. The project also includes an onshore/offshore seismic
component. A total of 90 short-period seismometers would be deployed on
the Raukumara Peninsula. The land seismometers would record seismic
energy from the R/V Langseth during the North Island 2-D and 3-D
surveys and would remain in place for three to four months to also
record earthquakes. This instrumentation allows for very deep seismic
sampling of the Hikurangi Subduction system to determine the structure
of the upper plate and properties of the deeper plate boundary zone.
North Island 3-D Survey
During the proposed North Island 3-D survey, approximately 3,025 km
of track lines would be surveyed within a 15 x 60 km survey area that
would begin at the Hikurangi trench and extend to within ~20 km of the
shoreline. Approximately 1 percent of the proposed North Island 3-D
survey would occur within New Zealand's territorial sea. The main goal
of the proposed North Island 3-D survey is to determine what conditions
are associated with slow slip behavior, how they differ from conditions
associated with subduction zones that generate great earthquakes, and
what controls the development of slow-slip faults instead of earthquake
prone faults. The PI and co-PIs propose to use MCS surveys to acquire
3-D seismic reflection data offshore New Zealand's Hikurangi trench and
forearc. Although not funded through NSF, international collaborators
would work with the PIs to achieve the research goals, providing
assistance, such as through logistical support and data acquisition and
exchange. This international collaborative experiment would record
Langseth shots during seismic acquisition and develop the first ever
high-resolution 3-D velocity models across a subduction zone using 3-D
full-waveform inversion, overlapping and extending beyond the 3-D
volume.
South Island 2-D Survey
During the South Island 2-D survey, marine seismic refraction data
would be collected along two east-west lines across the plate boundary.
One 200-km line would cross the Puysegur Trench at 49[deg] S., and
would be occupied by 20 short-period OBSs. A second line at 47.3[deg]
S. would be 260 km long with 23 OBSs. MCS profiles would occur along
these same two lines (thus each of the two lines would be surveyed
twice) as well as in between and within ~100 km north and south of the
two OBS lines. Approximately 4,876 km of track lines would be surveyed
during the proposed South Island 2-D survey. Approximately 6 percent of
those track lines would be within New Zealand's territorial sea.
The main goal of the South Island 2-D survey is to test models for
the formation of new subduction zones and to measure several
fundamental aspects of this poorly understood process. The study would
strive to (1) measure the angle of the new fault which forms the new
plate boundary and test ideas of how the faults form; (2) measure the
thickness of the oceanic crust at the Puysegur ridge and test models of
how the force from the nascent slab is transmitted into the plate; and
(3) measure the nature of the faults, especially the thrust faults, on
the over-riding plate and test models for how the forces on the over-
riding plate change with time. In addition, the airguns would be used
as a source of seismic waves that would be recorded onshore of the
South Island, to test models for the tectonic evolution and nature of
the shallow mantle directly below the plates. To achieve the project
goals of the South Island 2-D survey, the PI and co-PIs propose to use
MCS surveys to acquire a combination of 2-D MCS and refraction profiles
with OBSs along the Puysegur Ridge and Trench south of South Island.
Although not funded through NSF, international collaborators would work
with the PIs to achieve the research goals, providing assistance, such
as through logistical support and data acquisition and exchange. In
addition, the collaborators would use land seismometers to record
offshore airgun shots to determine the structure of the upper plate.
In addition to the operations of the airgun array, the ocean floor
would be mapped with a multibeam echosounder (MBES) and a sub-bottom
profiler (SBP). An Acoustic Doppler Current Profiler (ADCP) would be
used to measure water current velocities. These would operate
continuously during the proposed surveys, but not during transit to and
from the survey areas.
Proposed mitigation, monitoring, and reporting measures are
described in detail later in this document (please see ``Proposed
Mitigation'' and ``Proposed Monitoring and Reporting'').
Description of Marine Mammals in the Area of Specified Activities
Section 4 of the IHA application summarizes available information
regarding status and trends, distribution and habitat preferences, and
behavior and life history of the potentially affected species. More
general information about these species (e.g., physical and behavioral
descriptions) may be found on NMFS' Web site (www.nmfs.noaa.gov/pr/species/mammals/). Table 2 lists all species with expected potential
for occurrence in the Southwest Pacific Ocean off New Zealand and
summarizes information related to the population, including regulatory
status under the MMPA and ESA. The populations of marine mammals
considered in this document do not occur within the U.S. EEZ and are
therefore not assigned to stocks and are not assessed in NMFS' Stock
Assessment Reports (www.nmfs.noaa.gov/pr/sars/). As such, information
on potential biological removal (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) and on annual
levels of serious injury and mortality from anthropogenic sources are
not available for these marine mammal populations.
In addition to the marine mammal species known to occur in proposed
survey areas, there are 16 species of marine mammals with ranges that
are known to potentially occur in the waters of the proposed survey
areas, but they are categorized as ``vagrant'' under the New Zealand
Threat Classification System (Baker et al., 2016). These species are:
The ginkgo-toothed whale (Mesoplodon ginkgodens); pygmy beaked whale
(M. peruvianus); dwarf sperm whale (Kogia sima); pygmy killer whale
(Feresa attenuata); melon-headed whale (Peponocephala electra); Risso's
dolphin (Grampus griseus); Fraser's dolphin (Lagenodelphis hosei),
pantropical spotted dolphin (Stenella attenuata); striped dolphin (S.
coeruleoalba); rough-toothed dolphin (Steno bredanensis); Antarctic fur
seal (Arctocephalus gazelle); Subantarctic fur seal (A. tropicalis);
leopard seal (Hydrurga leptonyx); Weddell seal
[[Page 45119]]
(Leptonychotes weddellii); crabeater seal (Lobodon carcinophagus); and
Ross seal (Ommatophoca rossi). Except for Risso's dolphin and leopard
seal, for which there have been several sightings and strandings
reported in New Zealand (Clement 2010; Torres 2012; Berkenbusch et al.
2013; NZDOC 2017), the other ``vagrant'' species listed above are not
expected to occur in the proposed survey areas and are therefore not
considered further in this document.
Marine mammal abundance estimates presented in this document
represent the total number of individuals estimated within a particular
study or survey area. All values presented in Table 2 are the most
recent available at the time of publication.
Table 2--Marine Mammals That Could Occur in the Proposed Survey Areas
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ESA/MMPA status; Population
Common name Scientific name Stock strategic (Y/N) \1\ abundance \2\
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Order Cetartiodactyla--Cetacea--Superfamily Mysticeti (baleen whales)
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Family Balaenidae
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Southern right whale............. Eubalaena australis. N/A E/D;N \3\ 12,000
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Family Balaenopteridae (rorquals)
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Humpback whale................... Megaptera N/A -/-; N \3\ 42,000
novaeangliae.
Bryde's whale.................... Balaenoptera edeni.. N/A -/-; N \4\ 48,109
Common minke whale............... Balaenoptera N/A -/-; N \5\ \6\
acutorostrata. 750,000
Antarctic minke whale............ Balaenoptera N/A -/-; N \5\ \6\
bonaerensis. 750,000
Sei whale........................ Balaenoptera N/A E/D;- \5\ 10,000
borealis.
Fin whale........................ Balaenoptera N/A E/D;- \5\ 15,000
physalus.
Blue whale....................... Balaenoptera N/A E/D;- \3\ \5\ 3,800
musculus.
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Family Cetotheriidae
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Pygmy right whale................ Caperea marginata... N/A -/-; N N/A
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Superfamily Odontoceti (toothed whales, dolphins, and porpoises)
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Family Physeteridae
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Sperm whale...................... Physeter N/A E/D;- \5\ 30,000
macrocephalus.
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Family Kogiidae
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Pygmy sperm whale................ Kogia breviceps..... N/A -/-; N N/A
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Family Ziphiidae (beaked whales)
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Cuvier's beaked whale............ Ziphius cavirostris. N/A -/-; N \5\ \7\
600,000
Arnoux's beaked whale............ Berardius arnuxii... N/A -/-; N \5\ \7\
600,000
Shepherd's beaked whale.......... Tasmacetus shepherdi N/A -/-; N \5\ \7\
600,000
Hector's beaked whale............ Mesoplodon hectori.. N/A -/-; N \5\ \7\
600,000
True's beaked whale.............. Mesoplodon mirus.... N/A -/-; N N/A
Southern bottlenose whale........ Hyperoodon N/A -/-; N \5\ \7\
planifrons. 600,000
Gray's beaked whale.............. Mesoplodon grayi.... N/A -/-; N \5\ \7\
600,000
Andrew's beaked whale............ Mesoplodon bowdoini. N/A -/-; N \5\ \7\
600,000
Strap-toothed beaked whale....... Mesoplodon layardii. N/A -/-; N \5\ \7\
600,000
Blainville's beaked whale........ Mesoplodon N/A -/-; N \5\ \7\
densirostris. 600,000
Spade-toothed beaked whale....... Mesoplodon traversii N/A -/-; N \5\ \7\
600,000
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Family Delphinidae
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Bottlenose dolphin............... Tursiops truncatus.. N/A -/-; N N/A
Short-beaked common dolphin...... Delphinus delphis... N/A -/-; N N/A
Dusky dolphin.................... Lagenorhynchus N/A -/-; N \8\ 12,000-
obscurus. 20,000
Hourglass dolphin................ Lagenorhynchus N/A -/-; N \5\ 150,000
cruciger.
Southern right whale dolphin..... Lissodelphis peronii N/A -/-; N N/A
Risso's dolphin.................. Grampus griseus..... N/A -/-; N N/A
South Island Hector's dolphin.... Cephalorhynchus N/A T/D;- \9\ 14,849
hectori hectori.
Maui dolphin..................... Cephalorhynchus N/A E/D;- \10\ 55-63
hectori maui.
False killer whale............... Pseudorca crassidens N/A -/-; N N/A
Killer whale..................... Orcinus orca........ N/A -/-; N \5\ 80,000
Long-finned pilot whale.......... Globicephala melas.. N/A -/-; N \5\ 200,000
Short-finned pilot whale......... Globicephala N/A -/-; N N/A
macrorhynchus.
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[[Page 45120]]
Family Phocoenidae (porpoises)
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Spectacled porpoise.............. Phocoena dioptrica.. N/A -/-; N N/A
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Order Carnivora--Superfamily Pinnipedia
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Family Otariidae (eared seals and sea lions)
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New Zealand fur seal............. Arctocephalus N/A -/-; N \8\ 200,000
forsteri.
New Zealand sea lion............. Phocarctos hookeri.. N/A -/-; N \11\ 9,880
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Family Phocidae (earless seals)
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Leopard seal..................... Hydrurga leptonyx... N/A -/-; N \8\ 222,000
Southern elephant seal........... Mirounga leonina.... N/A -/-; N \8\ 607,000
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N/A = Not available or not assessed.
\1\ Endangered Species Act (ESA) status: Endangered (E), Threatened (T)/MMPA status: Depleted (D). A dash (-)
indicates that the species is not listed under the ESA or designated as depleted under the MMPA. Under the
MMPA, a strategic stock is one for which the level of direct human-caused mortality exceeds PBR or which is
determined to be declining and likely to be listed under the ESA within the foreseeable future. Any species or
stock listed under the ESA is automatically designated under the MMPA as depleted and as a strategic stock.
\2\ Abundance for the Southern Hemisphere or Antarctic unless otherwise noted.
\3\ IWC (2016).
\4\ IWC (1981).
\5\ Boyd (2002).
\6\ Dwarf and Antarctic minke whales combined.
\7\ All Antarctic beaked whales combined.
\8\ Estimate for New Zealand; NZDOC 2017.
\9\ Estimate for New Zealand; MacKenzie and Clement 2016.
\10\ Estimate for New Zealand; Hamner et al. (2014) and Baker et al. (2016).
\11\ Geschke and Chilvers (2009).
All species that could potentially occur in the proposed survey
area are included in table 2. However, of the species described in
Table 2, the temporal and/or spatial occurrence of one subspecies, the
Maui dolphin, is such that take is not expected to occur as a result of
the proposed project. The Maui dolphin is one of two subspecies of
Hector's dolphin (the other being the South Island Hector's dolphin),
both of which are endemic to New Zealand. The Maui dolphin has been
demonstrated to be genetically distinct from the South Island
subspecies of Hector's dolphin based on studies of mitochondrial and
nuclear DNA (Pichler et al. 1998). It is currently considered one of
the rarest dolphins in the world with a population size estimated at
just 55-63 individuals (Hamner et al. 2014; Baker et al. 2016).
Historically, Hector's dolphins are thought to have ranged along almost
the entire coastlines of both the North and South Islands of New
Zealand, though their present range is substantially smaller (Pichler
2002). The range of the Maui dolphin in particular has undergone a
marked reduction (Dawson et al. 2001; Slooten et al. 2005), with the
subspecies now restricted to the northwest coast of the North Island,
between Maunganui Bluff in the north and Whanganui in the south (Currey
et al., 2012). Occasional sightings and strandings have also been
reported from areas further south along the west coast as well as
possible sightings in other areas such as Hawke's Bay on the east coast
of North Island (Baker 1978, Russell 1999, Ferreira and Roberts 2003,
Slooten et al. 2005, DuFresne 2010, Berkenbusch et al. 2013; Torres et
al. 2013; Pati[ntilde]o-P[eacute]rez 2015; NZDOC 2017) though it is
unclear whether those individuals may have originated from the South
Island Hector's dolphin populations. A 2016 NMFS Draft Status Review
Report concluded the Maui dolphin is facing a high risk of extinction
as a result of small population size, reduced genetic diversity, low
theoretical population growth rates, evidence of continued population
decline, and the ongoing threats of fisheries bycatch, disease, mining
and seismic disturbances (Manning and Grantz, 2016). Due to its
extremely low population size and the fact that the subspecies is not
expected to occur in the proposed survey areas off the North Island,
take of Maui dolphins is not expected to occur as a result of the
proposed activities. Therefore the Maui dolphin is not discussed
further beyond the explanation provided here.
We have reviewed L-DEO's species descriptions, including life
history information, distribution, regional distribution, diving
behavior, and acoustics and hearing, for accuracy and completeness. We
refer the reader to Section 4 of L-DEO's IHA application, rather than
reprinting the information here. Below, for the 38 species that are
likely to be taken by the activities described, we offer a brief
introduction to the species and relevant stock as well as available
information regarding population trends and threats, and describe any
information regarding local occurrence.
Southern Right Whale
The southern right whale occurs throughout the Southern Hemisphere
between ~20[deg] S. and 60[deg] S. (Kenney 2009). Southern right whales
calve in nearshore coastal waters during the winter and typically
migrate to offshore feeding grounds during summer (Patenaude 2003).
Wintering populations off the subantarctic Auckland Islands of New
Zealand spend the majority of their time resting or engaging in social
interactions regardless of their group type (e.g. single whale, group,
and mother-calf pair). Over 35% of mother-calf pairs in the area were
seen traveling (Patenaude and Baker 2001).
[[Page 45121]]
Southern right whale sounds and their role in communication have
been fully described by Clark (1983) and are categorized into three
general classes (blow, slaps, and calls). Calls are generally low
frequency (peak frequencies <500 Hertz (Hz)) and one common call--
`Up'--has been described to function as a way for individuals to find
and make contact with each other.
The available information suggests that southern right whales could
be migrating near or within the proposed survey areas during October-
March, with the possibility of some individuals calving in nearshore
waters off eastern North Island during November. Habitat use (Torres et
al. 2013c) and suitability modeling (Pati[ntilde]o-P[eacute]rez 2015)
for New Zealand showed that a large proportion of the proposed North
and South Island survey areas (mainly in deeper water) has low habitat
suitability for the southern right whale; sheltered coastal areas had
the highest habitat suitability, especially in Foveaux Strait between
South and Stewart Islands.
Humpback Whale
Humpback whales are found worldwide in all ocean basins. In winter,
most humpback whales occur in the subtropical and tropical waters of
the Northern and Southern Hemispheres (Muto et al., 2015). These
wintering grounds are used for mating, giving birth, and nursing new
calves. In the South Pacific Ocean, there are several distinct winter
breeding grounds, including eastern Australia and Oceania (Anderson et
al. 2010; Garrigue et al. 2011; Bettridge et al. 2013). Whales from
Oceania migrate past New Zealand to Antarctic summer feeding areas
(Constantine et al. 2007; Garrigue et al. 2000, 2010); migration from
eastern Australia past New Zealand has also been reported (Franklin et
al. 2014). The northern migration along the New Zealand coast occurs
from May to August, with a peak in late June to mid-July; the southern
migration occurs from September to December, with a peak in late
October to late November (Dawbin 1956). It is likely that some humpback
whales would be encountered in the survey area during November and
December, as they migrate from winter breeding areas in the tropics to
summer feeding grounds in the Antarctic. Fewer humpbacks are expected
to occur in the proposed survey areas during January through March, as
most individuals occur further south during the summer.
Humpback whales were listed as endangered under the Endangered
Species Conservation Act (ESCA) in June 1970. In 1973, the ESA replaced
the ESCA, and humpbacks continued to be listed as endangered. NMFS
recently evaluated the status of the species, and on September 8, 2016,
NMFS divided the species into 14 distinct population segments (DPS),
removed the current species-level listing, and in its place listed four
DPSs as endangered and one DPS as threatened (81 FR 62259; September 8,
2016). The remaining nine DPSs were not listed. The only DPSs with the
potential to occur in the proposed survey areas would be the Oceania
DPS and the Eastern Australia DPS; neither of these DPSs is listed
under the ESA (81 FR 62259; September 8, 2016).
Bryde's Whale
The Bryde's whale occurs in all tropical and warm temperate waters
in the Pacific, Atlantic, and Indian oceans, between 40[deg] N. and
40[deg] S. (Kato and Perrin 2009). It is one of the least known large
baleen whales, and it remains uncertain how many species are
represented in this complex (Kato and Perrin 2009). Bryde's whales
remain in warm (>16 [deg]C) water year-round, and seasonal movements
towards the Equator in winter and offshore in summer have been recorded
(Kato and Perrin 2009). The Bryde's whale is likely to occur in the Bay
of Plenty in the proposed North Island survey area; it is unlikely to
occur anywhere else in the North Island or South Island survey areas.
Minke Whale
The minke whale has a cosmopolitan distribution ranging from the
tropics and sub-tropics to the ice edge in both hemispheres (Jefferson
et al. 2015). Its distribution in the Southern Hemisphere is not well
known (Jefferson et al. 2015). Populations of minke whales around New
Zealand are migratory (Baker 1983). Clement (2010) noted that minke
whales likely use East Cape to navigate along the east coast of New
Zealand during the northern and southern migrations. Small groups of
minke whales have been sighted off New Zealand (Baker 1999; Clement
2010; Berkenbusch et al. 2013; Torres et al. 2013b; Pati[ntilde]o-
P[eacute]rez 2015).
Antarctic Minke Whale
The Antarctic minke whale has a circumpolar distribution in coastal
and offshore areas of the Southern Hemisphere from ~7[deg] S. to the
ice edge (Jefferson et al. 2015). Antarctic minke whales are found
between 60[deg] S. and the ice edge during the austral summer (December
to February); in the austral winter (June to August), they are mainly
found at breeding grounds at mid latitudes, including 10[deg] S.-
30[deg] S. and 170[deg] E.-100[deg] W. in the Pacific, off eastern
Australia (Perrin and Brownell 2009). Antarctic minke whales would be
less likely to be encountered during the time of the proposed surveys,
because they would be expected to be in their summer feeding areas
further south.
Sei Whale
The sei whale occurs in all ocean basins (Horwood 2009) but appears
to prefer mid-latitude temperate waters (Jefferson et al. 2008). It
undertakes seasonal migrations to feed in subpolar latitudes during
summer and returns to lower latitudes during winter to calve (Horwood
2009). The sei whale is pelagic and generally not found in coastal
waters (Harwood and Wilson 2001). It occurs in deeper waters
characteristic of the continental shelf edge region (Hain et al. 1985)
and in other regions of steep bathymetric relief such as seamounts and
canyons (Kenney and Winn 1987; Gregr and Trites 2001). In the South
Pacific, sei whales typically concentrate between the sub-tropical and
Antarctic convergences during the summer (Horwood 2009). The sei whale
is likely to be uncommon in the proposed survey areas during October-
March.
Fin Whale
Fin whales are found throughout all oceans from tropical to polar
latitudes, however, their overall range and distribution is not well
known (Jefferson et al. 2015). The fin whale most commonly occurs
offshore but can also be found in coastal areas (Aguilar 2009). Most
populations migrate seasonally between temperate waters where mating
and calving occur in winter, and polar waters where feeding occurs in
summer (Aguilar 2009). However, recent evidence suggests that some
animals may remain at high latitudes in winter or low latitudes in
summer (Edwards et al. 2015). Northern and southern fin whale
populations are distinct and are sometimes recognized as different
subspecies (Aguilar 2009). In the Southern Hemisphere, fin whales are
usually distributed south of 50 [deg]S. in the austral summer, and they
migrate northward to breed in the winter (Gambell 1985).
Blue Whale
The blue whale has a cosmopolitan distribution and tends to be
pelagic, only coming nearshore to feed and possibly to breed (Jefferson
et al. 2008). Blue whale migration is less well defined than for some
other rorquals, and their movements tend to be more closely linked to
areas of high primary productivity, and hence prey, to meet
[[Page 45122]]
their high energetic demands (Branch et al. 2007). Generally, blue
whales are seasonal migrants between high latitudes in the summer,
where they feed, and low latitudes in the winter, where they mate and
give birth (Lockyer and Brown 1981). Some individuals may stay in low
or high latitudes throughout the year (Reilly and Thayer 1990; Watkins
et al. 2000).
Three subspecies of blue whale are recognized: B. m. musculus in
the Northern Hemisphere; B. m. intermedia (the true blue whale) in the
Antarctic, and B. m. brevicauda (the pygmy blue whale) in the sub-
Antarctic zone of the southern Indian Ocean and the southwestern
Pacific Ocean (Sears and Perrin 2009). The pygmy and Antarctic blue
whale occur in New Zealand (Branch et al. 2007). The blue whale is
considered rare in the Southern Ocean (Sears and Perrin 2009). Most
pygmy blue whales do not migrate south during summer; however,
Antarctic blue whales are typically found south of 55[deg] S. during
summer, although some are known not to migrate (Branch et al. 2007).
Blue whale calls have been detected in New Zealand waters year-
round (Miller et al. 2014). Vocalizations have been recorded within 2
km from Great Barrier Island, northern New Zealand, from June to
December 1997 (McDonald 2006), as well as off the tip of Northland
(Miller et al. 2014). Blue whale vocalizations were also detected along
the west and east coasts of South Island during January-March 2013;
these included songs detected in four locations off the southwest tip
of the South Island in early February and at multiple locations south
of Stewart Island in mid-March (Miller et al. 2014). Southern Ocean
blue whale songs were detected further offshore during May-July
(McDonald 2006).
Pygmy Right Whale
The pygmy right whale is the smallest, most cryptic and least known
of the living baleen whales. Pygmy right whales are found individually
or in pairs, although groups of up to 80 whales have been observed.
Although little is known about them, it is thought that pygmy right
whales do not exhibit common behaviors of other whales such as
breaching or displaying their flukes. In one case, a pygmy right whale
was observed swimming by undulating the body from head to tail rather
than swimming using movement of the tail area and flukes like other
cetaceans. Pygmy right whales are strong, fast swimmers (Fordyce 2013).
The pygmy right whale's distribution is circumpolar in the Southern
Hemisphere between 30[deg] S. and 55[deg] S. in oceanic and coastal
environments (Kemper 2009; Jefferson et al. 2015). Pygmy right whales
appear to be non-migratory, although there may be some movement inshore
during spring and summer (Kemper 2002). Strandings appear to be
associated with favorable feeding areas in New Zealand, including
upwelling regions, along the Subtropical Convergence, and the Southland
Current (Kemper 2002; Kemper et al. 2013). Despite the scarcity of
sightings, Kemper (2009) noted that the number of strandings indicate
that the pygmy right whale may be relatively common in Australia and
New Zealand.
Sperm Whale
Sperm whales are found throughout the world's oceans in deep waters
from the tropics to the edge of the ice at both poles (Leatherwood and
Reeves 1983; Rice 1989; Whitehead 2002). Sperm whales throughout the
world exhibit a geographic social structure where females and juveniles
of both sexes occur in mixed groups and inhabit tropical and
subtropical waters. Males, as they mature, initially form bachelor
groups but eventually become more socially isolated and more wide-
ranging, inhabiting temperate and polar waters as well (Whitehead
2003). Females typically inhabit waters >1000 m deep and latitudes
<40[deg] (Rice 1989). Torres et al. (2013a) found that sperm whale
distribution is associated with proximity to geomorphologic features,
as well as surface temperature.
Sperm whales are widely distributed throughout New Zealand waters,
occurring in offshore and nearshore regions, with decreasing abundance
away from New Zealand toward the central South Pacific Ocean (Gaskin
1973). Sperm whale sightings have been reported throughout the year in
and near the proposed North Island survey area, including the Bay of
Plenty and off East Cape (Clement 2010; Berkenbusch et al. 2013; Torres
et al. 2013b; Blue Planet Marine 2016; NZDOC 2017b), as well as in and
near the South Island survey area (Berkenbusch et al. 2013; NZDOC
2017b). Although sightings have been made during the summer in the
proposed North Island survey area, no summer sightings were reported
for the South Island survey area. However, sightings were made just to
the south of the proposed survey area during summer (Kasamatsu and
Joynce 1995). There have been at least 211 strandings reported for New
Zealand (Berkenbusch et al. 2013), including along the coast of East
Cape, in Hawke's Bay, Cook Strait, and along the south coast of South
Island (Brabyn 1991; NZDOC 2017b).
Pygmy Sperm Whale
Pygmy sperm whales are found in tropical and warm-temperate waters
throughout the world (Ross and Leatherwood 1994) and prefer deeper
waters with observations of this species in greater than 4,000 m depth
(Baird et al., 2013). Sightings are rare of this species. They are
difficult to sight at sea, because of their dive behavior and perhaps
because of their avoidance reactions to ships and behavior changes in
relation to survey aircraft (W[uuml]rsig et al. 1998). Both pygmy and
dwarf sperm whales are sighted primarily along the continental shelf
edge and slope and over deeper waters off the shelf (Hansen et al.
1994; Davis et al. 1998; Jefferson et al. 2008).
There have been very few sightings of pygmy sperm whales in New
Zealand. The lack of sightings is likely because of their subtle
surface behavior and long dive times (Clement 2010). However, the pygmy
sperm whale is one of the most regularly stranded cetacean species in
New Zealand, suggesting that this species is relatively common in those
waters (Clement 2010). Pygmy sperm whales are likely to occur near the
North Island survey area but are less likely to occur in the South
Island survey area.
Cuvier's Beaked Whale
Cuvier's beaked whale is the most widespread of the beaked whales
occurring in almost all temperate, subtropical, and tropical waters and
even some sub-polar and polar waters (MacLeod et al. 2006). It is found
in deep water over and near the continental slope (Jefferson et al.
2008). New Zealand has been reported as a hotspot for beaked whales
(MacLeod and Mitchell 2006), with both sightings and strandings of
Cuvier's beaked whales in the proposed survey area (MacLeod et al.
2006; Thompson et al. 2013a).
Cuvier's beaked whales strand relatively frequently in New Zealand;
at least 82 strandings have been reported (Berkenbusch et al. 2013).
For the North Island, strandings have been reported for the Bay of
Plenty, East Cape, Mahia Peninsula, Hawke's Bay, as well as Cook
Strait; strandings have occurred along all coasts of South Island
(Brabyn 1991; Clement 2010; Thompson et al. 2013a). Strandings have
been reported throughout the year, with a peak during fall (Thompson et
al. 2013a).
Arnoux's Beaked Whale
Arnoux's beaked whale is distributed in deep, temperate and
subpolar waters of the Southern Hemisphere, with most
[[Page 45123]]
records for southeast South America, the Antarctic Peninsula, South
Africa, New Zealand, and southern Australia (Jefferson et al. 2015). It
typically occurs south of 40[deg] S., but it could reach latitudes of
34[deg] S. or even farther north (Jefferson et al. 2015). Arnoux's
beaked whale strands frequently in New Zealand (Ross 2006), with
strandings reported for the northwest coast of North Island, Bay of
Plenty, Hawke's Bay, and Cook Strait (Clement 2010; Thompson et al.
2013a). MacLeod et al. (2006) reported numerous strandings of Berardius
spp. for New Zealand. One sighting has been made in the Bay of Plenty
(Clement 2010).
Shepherd's Beaked Whale
Based on known records, it is likely that Shepherd's beaked whale
has a circumpolar distribution in the cold temperate waters of the
Southern Hemisphere (Mead 1989a). This species is primarily known from
strandings, most of which have been recorded in New Zealand (Mead
2009). Thus, MacLeod and Mitchell (2006) suggested that New Zealand may
be a globally important area for Shepherd's beaked whale. However, only
a few sightings of live animals have been reported for New Zealand
(MacLeod and Mitchell 2006). One possible sighting was made near
Christchurch (Watkins 1976). In 2016, there were two sightings of
Shepherd's beaked whale on a winter survey offshore from the Otago
Peninsula on the South Island (NZDOC 2017b). At least 20 specimens have
stranded on the coast of New Zealand (Baker 1999), including in
southern Taranaki Bight and Banks Peninsula (Brabyn 1991). Stranding
records also exist for Mahia Peninsula and northeastern North Island
(Thompson et al. 2013a).
Hector's Beaked Whale
Hector's beaked whale is thought to have a circumpolar distribution
in deep oceanic temperate waters of the Southern Hemisphere (Pitman
2002). Based on the number of stranding records for the species, it
appears to be relatively rare. One individual was observed swimming
close to shore off southwestern Australia for periods of weeks before
disappearing (Gales et al. 2002). This was the first live sighting in
which species identity was confirmed.
MacLeod and Mitchell (2006) suggested that New Zealand may be a
globally important area for this species. There are sighting and
stranding records of Hector's beaked whales for New Zealand (MacLeod et
al. 2006; Clement 2010). One sighting has been reported for the Bay of
Plenty on the North Island (Clement 2010). At least 12 strandings have
been reported for New Zealand (Berkenbusch et al. 2013), including
records for the Bay of Plenty, East Cape, Mahia Peninsula, Hawke's Bay,
Cook Strait, and the east coast of South Island (Brabyn 1991; Clement
2010; Thompson et al. 2013a; NZDOC 2017b).
True's Beaked Whale
True's beaked whale has a disjunct, antitropical distribution in
the Northern and Southern hemispheres (Jefferson et al. 2015). In the
Southern Hemisphere, it is known to occur in the Atlantic and Indian
oceans, including Brazil, South Africa, Madagascar, and southern
Australia (Jefferson et al. 2015). There is a single record of True's
beaked whale in New Zealand, which stranded on the west coast of South
Island in November 2011 (Constantine et al. 2014).
Southern Bottlenose Whale
The southern bottlenose whale can be found throughout the Southern
Hemisphere from 30[deg] S. to the ice edge, with most sightings
occurring from ~57[deg] S. to 70[deg] S. (Jefferson et al. 2015). It is
apparently migratory, occurring in Antarctic waters during summer
(Jefferson et al. 2015). New Zealand has been reported as a hotspot for
beaked whales (MacLeod and Mitchell 2006), with both sightings and
strandings of southern bottlenose whales in the area (MacLeod et al.
2006). At least six sightings have been reported for waters around New
Zealand, including one in Hauraki Gulf, one on the southwest coast of
South Island, one off the east coast of North Island within the
proposed survey area, one off the Otago Peninsula, and two sightings
south of New Zealand within the EEZ (Berkenbusch et al. 2013; NZDOC
2017b). In addition, 24 strandings were reported for New Zealand
between 1970 and 2013 (Berkenbusch et al. 2013). Strandings have been
reported for Bay of Plenty, East Cape, Hawke's Bay, southern North
Island, northeastern South Island, and Cook Strait (Brabyn 1991;
Clement 2010; Thompson et al. 2013a).
Gray's Beaked Whale
Gray's beaked whale is thought to have a circumpolar distribution
in temperate waters of the Southern Hemisphere (Pitman 2002). Gray's
beaked whale primarily occurs in deep waters beyond the edge of the
continental shelf (Jefferson et al. 2015). Some sightings have been
made in very shallow water, usually of sick animals coming in to strand
(Gales et al. 2002; Dalebout et al. 2004). One Gray's beaked whale was
observed within 200 m of the shore off southwestern Australia off and
on for periods of weeks before disappearing (Gales et al. 2002). There
are many sighting records from Antarctic and sub-Antarctic waters, and
in summer months they appear near the Antarctic Peninsula and along the
shores of the continent (sometimes in the sea ice).
New Zealand has been reported as a hotspot for beaked whales
(MacLeod and Mitchell 2006), with both sightings and strandings of
Gray's beaked whales in the proposed survey area (MacLeod et al. 2006;
Thompson et al. 2013a). In particular, the area between the South
Island of New Zealand and the Chatham Islands has been suggested to be
a hotspot for sightings of this species (Dalebout et al. 2004).
Andrew's Beaked Whale
Andrew's beaked whale has a circumpolar distribution in temperate
waters of the Southern Hemisphere (Baker 2001). This species is known
only from stranding records between 32[deg] S. and 55[deg] S., with
more than half of the strandings occurring in New Zealand (Jefferson et
al. 2015). Thus, New Zealand may be a globally important area for
Andrew's beaked whale (MacLeod and Mitchell 2006). In particular,
Clement (2010) suggested that the East Cape/Hawke's Bay waters may be
an important habitat for Andrew's beaked whale.
There have been at least 19 strandings in New Zealand (Berkenbusch
et al. 2013), at least 10 of which have been reported in the spring and
summer (Baker 1999). Strandings have occurred from the North Island to
the sub-Antarctic Islands (Baker 1999), including East Cape, Hawke's
Bay, Cook Strait, and southeast of Stewart Island (Brabyn 1991; Clement
2010; Thompson et al. 2013a).
Strap-Toothed Beaked Whale
The strap-toothed beaked whale is thought to have a circumpolar
distribution in temperate and sub-Antarctic waters of the Southern
Hemisphere, mostly between 35[deg] and 60[deg] S. (Jefferson et al.
2015). Based on the number of stranding records, it appears to be
fairly common. Strap-toothed whales are thought to migrate northward
from Antarctic and sub-Antarctic latitudes during April-September
(Sekiguchi et al. 1996).
New Zealand has been reported as a hotspot for beaked whales
(MacLeod and Mitchell 2006), with both sightings and strandings of
strap-toothed beaked whales adjacent to the proposed survey area
(MacLeod et al. 2006; Clement 2010; Thompson et al. 2013a). Strap-
toothed whales commonly strand in
[[Page 45124]]
New Zealand, with at least 78 strandings reported (Berkenbusch et al.
2013). Most strandings occur between January and April, suggesting some
seasonal austral summer inshore migration (Baker 1999; Thompson et al.
2013a). Strap-toothed whale strandings have been reported for the east
coast of North Island and South Island, including the Bay of Plenty,
East Cape, Hawke's Bay, Cook Strait, the Otago Peninsula and along
Foveaux Strait (Brabyn 1991; Clement 2010; Thompson et al. 2013a).
Blainville's Beaked Whale
Blainville's beaked whale is found in tropical and warm temperate
waters of all oceans; it has the widest distribution throughout the
world of all mesoplodont species and appears to be common (Pitman
2009b). In the western Pacific, strandings have been reported from
Japan to Australia and New Zealand (MacLeod et al. 2006). There have
been at least four strandings of Blainville's beaked whale in New
Zealand, including three strandings for the northwest coast of North
Island and another for Hawke's Bay, but none for the South Island
(Thompson et al. 2013a).
Spade-Toothed Beaked Whale
The spade-toothed beaked whale is the name proposed for the species
formerly known as Bahamonde's beaked whale (M. bahamondi). Recent
genetic evidence has shown that they belong to the species first
identified by Gray in 1874 (van Helden et al. 2002). The species is
considered relatively rare and is known from only four records, three
of which are from New Zealand (Thompson et al. 2012). One mandible was
found at the Chatham Islands in 1872; two skulls were found at White
Island, Bay of Plenty, in the 1950s; a skull was collected at Robinson
Crusoe Island, Chile, in 1986; and most recently, two live whales, a
female and a male, stranded at Opape, in the Bay of Plenty, and
subsequently died (Thompson et al. 2012). MacLeod and Mitchell (2006)
suggested that New Zealand may be a globally important area for the
spade-toothed beaked whale.
Bottlenose Dolphin
Bottlenose dolphins are widely distributed throughout the world in
tropical and warm-temperate waters (Perrin et al. 2009). Generally,
there are two distinct bottlenose dolphin ecotypes: One mainly found in
coastal waters and one mainly found in oceanic waters (Duffield et al.
1983; Hoelzel et al. 1998; Walker et al. 1999). As well as inhabiting
different areas, these ecotypes differ in their diving abilities
(Klatsky 2004) and prey types (Mead and Potter 1995).
Short-Beaked Common Dolphin
The short-beaked common dolphin is found in tropical to cool
temperate oceans around the world, and ranges as far south as ~40[deg]
S. (Perrin 2009). It is generally considered an oceanic species
(Jefferson et al. 2015), but Neumann (2001) noted that this species can
be found in coastal and offshore habitats. Short-beaked common dolphins
are found in shelf waters of New Zealand, generally north of Stewart
Island; they are more commonly seen in waters along the northeastern
coast of North Island (Stockin and Orams 2009; NABIS 2017) and may
occur closer to shore during the summer (Neumann 2001; Stockin et al.
2008). They can be found all around New Zealand (Baker 1999) with
abundance hotspots on the coasts of Northland, Hauraki Gulf, Mahia
Peninsula, Cape Palliser, Cook Strait, Marlborough Sounds, and the
northwest coast of South Island (NABIS 2017).
The short-beaked common dolphin is likely the most common cetacean
species in New Zealand waters, occurring there year-round (Clement
2010; Hutching 2015). Numerous sightings have been made in shelf waters
of the east coast of North and South Islands, as well as farther
offshore, throughout the year, including within the proposed survey
areas (Clement 2010; Berkenbusch et al. 2013; Torres et al. 2013b;
Pati[ntilde]o-P[eacute]rez 2015; Blue Planet Marine 2016; NZDOC 2017b).
Dusky Dolphin
The dusky dolphin is found throughout the Southern Hemisphere,
occurring in disjunct subpopulations in the waters off southern
Australia, New Zealand (including some sub-Antarctic Islands), central
and southern South America, and southwestern Africa (Jefferson et al.
2015). The species occurs in coastal and continental slope waters and
is uncommon in waters >2000 m deep (W[uuml]rsig et al 2007). The dusky
dolphin is common in New Zealand (Hutching 2015) and occurs there year-
round. Dusky dolphins migrate northward to warmer waters in winter and
south during the summer (Gaskin 1968).
Sightings of dusky dolphins exist for shelf as well as deep,
offshore waters (Berkenbusch et al. 2013). W[uuml]rsig et al. (2007)
noted that dusky dolphins typically move into deeper waters during the
winter. Sightings have been made in and near the proposed North and
South Island survey areas during summer (see Clement 2010; Berkenbusch
et al. 2013; Pati[ntilde]o-P[eacute]rez 2015; Blue Planet Marine 2016;
NZDOC 2017b). Some sightings in the austral spring and summer have been
made along Northland, Bay of Plenty, off East Cape, southeast coast of
North Island, Cape Palliser, and Cook Strait (Berkenbusch et al. 2013;
NZDOC 2017b). However, sightings off the entire coastline of South
Island appear to be more common and are made throughout the year.
Hourglass Dolphin
The hourglass dolphin occurs in all parts of the Southern Ocean
south of ~45[deg] S., with most sightings between 45[deg] S. and
60[deg] S. (Goodall 2009). Although it is pelagic, it is also sighted
near banks and Islands (Goodall 2009). Baker (1999) noted that the
hourglass dolphin is considered a rare coastal visitor to New Zealand.
Berkenbusch et al. (2013) reported five sightings of hourglass dolphins
in New Zealand waters, including one off Banks Peninsula, one off the
southeast coast of South Island, two within the proposed South Island
survey, and one southwest of the Auckland Islands. All sightings were
made during November-February. In addition, there have been at least
five strandings in New Zealand (Berkenbusch et al. 2013), including
records for the South Island (Baker 1999). Due to these observations,
the hourglass dolphin would likely be rare in the proposed North survey
area and uncommon in the South Island survey area.
Southern Right Whale Dolphin
The southern right whale dolphin is distributed between the
Subtropical and Antarctic Convergences in the Southern Hemisphere,
generally between ~30[deg] S. and 65[deg] S. (Jefferson et al. 2015).
It is sighted most often in cool, offshore waters, although it is
sometimes seen near shore where coastal waters are deep (Jefferson et
al. 2015). The species has rarely been seen at sea in New Zealand
(Baker 1999). Berkenbusch et al. (2013) reported five sightings for the
EEZ of New Zealand, including one each off the southeast coast and
southwest coast of South Island, and three to the southeast of Stewart
Island; sightings were made during February and September. During
August 1999, a group 500+ southern right whale dolphins including a
calf were sighted southeast of Kaikoura in water >1500 m deep (Visser
et al. 2004). There were five additional sightings in the OBIS
database, including one sighting in the South Taranaki Bight, two
sightings
[[Page 45125]]
southeast of Kaikoura during 1985-1986, and two sightings off the
southwest coast of South Island (OBIS 2017). Several more sightings
have also been reported off the southeast coast of South Island (NZDOC
2017b).
At least 16 strandings have been reported for New Zealand
(Berkenbusch et al. 2013). Most strandings have occurred along the
north coast of South Island (Brabyn 1991), but strandings were also
reported for Hawke's Bay, southeast North Island, Banks Peninsula, and
Foveaux Strait (Clement 2010; NZDOC 2017b).
Risso's Dolphin
Risso's dolphins are found in tropical to warm-temperate waters
(Carretta et al., 2016). The species occurs from coastal to deep water
but is most often found in depths greater than 3,000 m with the highest
sighting rate in depths greater than 4,500 m (Baird 2016) and is known
to frequent seamounts and escarpments (Kruse et al. 1999). It occurs
between 60[deg] N. and 60[deg] S. where surface water temperatures are
at least 10 [deg]C (Kruse et al. 1999).
According to Jefferson et al. (2014, 2015), the range of the
Risso's dolphin includes the waters of New Zealand, although the number
of records for that region is small. Nonetheless, a few records exist
for the North Island, including the east coast (Clement 2010;
Berkenbusch et al. 2013; Jefferson et al. 2014). Although some
sightings have been reported in New Zealand, such as in South Taranaki
Bight on the west coast of North Island (Torres 2012), only strandings
are known for the east coast of North Island (Clement 2010). One
stranding has been reported for the northwest coast of South Island
(NZDOC 2017b).
South Island Hector's Dolphin
Hector's dolphins are endemic to New Zealand and have one of the
most restricted distributions of any cetacean (Dawson and Slooten
1988); they occur in New Zealand waters year-round (Berkenbusch et al.
2013) and are found mainly in coastal waters, preferring depths of <90
m (Br[auml]ger et al. 2003; Rayment et al. 2006; Slooten et al. 2006)
within 10 km from shore (Hutching 2015). As described above, the South
Island Hector's dolphin (C. hectori hectori) is one of two subspecies
of Hector's dolphins that have been formally recognized on the basis of
multiple morphological distinctions and genetic evidence of
reproductive isolation (Baker et al., 2002; Pichler 2002, Hamner et
al., 2012).
Historically, Hector's dolphins are thought to have ranged along
almost the entire coastlines of both the North and South Islands of New
Zealand, though their present range is substantially smaller (Pichler
2002). The South Island Hector's dolphin is found only off the coast of
the South Island of New Zealand (L. Manning and K. Grantz, 2016). There
are at least three genetically separate populations of Hector's dolphin
off South Island: Off the east coast (particularly around Banks
Peninsula), off the west coast, and off the Southland coast of southern
South Island (Baker et al. 2002). The majority of Hector's dolphins off
the South Island are found along the West Coast (between Farewell Spit
and Milford Sound) with the remainder (about 1200 to 2900) found along
the East Coast (from Farewell Spit to Nugget Point) and South Coast
(from Nugget Point to Long Point) (Dawson et al. 2004).
False Killer Whale
The false killer whale is found in all tropical and warm temperate
oceans of the world, with only occasional sightings in cold temperate
waters (Baird 2009b). It is known to occur in deep, offshore waters
(Odell and McClune 1999), but can also occur over the continental shelf
and in nearshore shallow waters (Jefferson et al. 2015; Zaeschmar et
al. 2014). In the western Pacific, the false killer whale is
distributed from Japan south to Australia and New Zealand.
Berkenbusch et al. (2013) reported at least 27 sightings of false
killer whales in New Zealand during summer and fall, primarily along
the coast of North Island, but also off South Island and in South
Taranaki Bight. In addition, there have been at least 28 strandings in
New Zealand (Zaeschmar 2014), including along East Cape, Hawke's Bay,
Cape Palliser, Cook Strait, Otago Peninsula, and Catlin's coast (Brabyn
1991; Clement 2010; NZDOC 2017b). The strandings include a mass
stranding on North Island (~37 [deg] S.) of 231 whales in March 1978
(Baker 1999).
Killer Whale
Killer whales have been observed in all oceans and seas of the
world (Leatherwood and Dahlheim 1978). Although reported from tropical
and offshore waters (Heyning and Dahlheim 1988), killer whales prefer
the colder waters of both hemispheres, with greatest abundances found
within 800 km of major continents (Mitchell 1975). High densities of
the species occur in high latitudes, especially in areas where prey is
abundant.
The killer whale has been reported to be common in New Zealand
waters (Baker 1999), with a population of ~200 individuals (Suisted and
Neale 2004). Killer whales have been sighted in all months around North
and South Islands (Berkenbusch et al. 2013; Torres 2012; NABIS 2017).
Calves and juveniles occur there throughout the year (Visser 2000).
Only the Type A killer whale is considered resident in New Zealand,
while Types B, C, and D are vagrant and most common in the Southern
Ocean (Visser 2000, 2007; Baker et al. 2010, 2016a). As sighting of
killer whales have been made near and within the survey areas during
austral spring and summer, killer whales could occur in small numbers
near the project areas.
Long-Finned Pilot Whale
Long-finned pilot whales roam throughout the cold temperate waters
of the Southern Hemisphere. They live in stable family groups, and
offspring of both sexes stay in their mother's pod throughout their
lives. Each pod numbers 20-100 whales, though they can congregate in
much larger numbers. Pilot whales are prolific stranders, and this
behavior is not well understood. There are recordings of individual
strandings all over New Zealand, and there are a few mass stranding
``hotspots'' at Golden Bay, Stewart Island, and the Chatham Islands.
Due to this, it is possible for the proposed survey to encounter
species.
Short-Finned Pilot Whale
Short finned pilot whales tend to inhabit more sub-tropical and
tropical zones. Although long-finned and short-finned pilot whales are
readily distinguishable by differences in tooth count, flipper length,
and skull morphology, it is almost impossible to distinguish between
the two species at sea. The species prefers deeper waters, ranging from
324 m to 4,400 m, with most sightings between 500 m and 3,000 m (Baird
2016).
Short-finned pilot whale stranding records exist for the Bay of
Plenty, East Cape, Hawke's Bay, off Banks Peninsula, and the southeast
coast of South Island. While most pilot whales sighted south of
~40[deg] S., would likely be the long-finned variety, short-finned
pilot whales could also be encountered during the survey, particularly
off the northeast coast of North Island.
Spectacled Porpoise
The spectacled porpoise is circumpolar in cool temperate, sub-
Antarctic, and low Antarctic waters (Goodall 2009). It is thought to be
oceanic in temperate to sub-Antarctic waters and is often sighted in
deep waters far from land (Goodall 2009).
[[Page 45126]]
Little is known regarding the distribution and abundance of the
species, but it is believed to be rare throughout most of its range
(Goodall and Schiavini 1995). Only five sightings were made during 10
years (1978/79-1987/88) of extensive Antarctic surveys for minke whales
(Kasamatsu et al. 1990). An additional 23 at-sea sightings described in
Sekiguchi et al. (2006) have expanded the knowledge of the species. The
sightings were circumpolar, mostly in offshore waters with sea surface
temperatures of 0.9-10.3 [deg]C, with a concentration south of the
Auckland Islands (Sekiguchi et al. 2006). Sightings have been reported
for the west coast of Northland and off the southeast coast of South
Island (NZDOC 2017b). Strandings have occurred along the Bay of Plenty,
South Taranaki Bight, Banks Peninsula, Otago Peninsula, Catlins Coast,
and the Auckland Islands (NZDOC 2017b). The spectacled porpoise is
rare; it is not expected to occur in the proposed North Island survey
area but could occur off South Island.
New Zealand Fur Seal
New Zealand fur seals are found on rocky shores around the
mainland, Chatham Islands and the Subantarctic islands (including
Macquarie Island) of New Zealand. They are also found much further
afield in South Australia, Western Australia and Tasmania. Off Otago,
New Zealand fur seal's prey stay very deep underwater during the day,
and then come closer to the surface at night. Here, fur seals feed
almost exclusively at night, when prey is closer to the surface, as
deep as 163 m during summer. Their summer foraging is concentrated over
the continental shelf, or near the slope. They will dive continuously
from sundown to sunrise. In autumn and winter, they dive much deeper
with many dives greater than 100 m. At least some females dive deeper
than 240 m, and from satellite tracking they may forage up to 200 km
beyond the continental slope in water deeper than 1000 m (NZDOC 2017a).
On the east coast of North Island, there are at least 15 haul-out
sites and three breeding areas between Cape Palliser and Bay of Plenty,
including haul out sites along Hawke's Bay, on East Cape, and in the
Bay of Plenty (Clement 2010). In addition, there are also at least two
haul-out sites along the northeast coast of South Island (Taylor et al.
1995). Numerous nearshore and offshore sightings have been made within
the proposed survey area east of North Island from seismic vessels off
the southeast coast of North Island (Blue Planet Marine 2016; SIO
n.d.). New Zealand fur seals would likely be encountered during the
proposed surveys off the North and South Islands.
New Zealand Sea Lion
The New Zealand sea lion is New Zealand's only endemic pinniped. It
is one of the world's rarest pinnipeds, with a highly restricted
breeding range between 50 [deg] S. and 53 [deg] S., primarily on the
Auckland (50 [deg] S., 166 [deg] E.) and Campbell islands (52[deg]33
S., 169[deg]09 E.) (Gales & Fletcher 1999; McNally 2001; Childerhouse
et al. 2005).
Sea lions that were satellite-tracked in the Auckland Islands
during January and February foraged over the entire shelf out to a
water depth of 500 m (Chilvers 2009; Meynier et al. 2014) and beyond
(Geschke and Chilvers 2009), including near the southeastern-most edge
of the proposed survey area. New Zealand sea lions are also known to
forage on arrow squid near Snares Islands (Lalas and Webster 2013).
Numerous nearshore and offshore sightings have been made off South
Island from seismic vessels, including off the southeast coast, east of
Stewart Island, and east of Snares Island (Blue Planet Marine 2016). It
is possible that New Zealand sea lions would be encountered during the
proposed survey off South Island, but unlikely that they would be
encountered in the proposed survey areas off North Island.
Leopard Seal
Adult leopard seals are normally found along the edge of the
Antarctic pack ice but in winter, young animals move throughout the
Southern Ocean and occasionally occur in New Zealand, including the
Auckland and Campbell Islands, and the mainland (NZDOC 2017a). Auckland
and Campbell islands are known to have leopard seals annually and the
mainland regularly receives visitors (NZDOC 2017a). Numerous sightings
have been made along the North and South Islands, not only in the
winter but also during January-March (NZDOC 2017b). Sightings for the
North Island include Cook Strait, Cape Palliser, the Bay of Plenty, and
Hauruki Gulf; there is also one record for offshore waters of the study
area off the southeast coast of North Island. For the South Island,
sightings have been reported on all coasts, including Forveaux Strait
and Stewart Island off the south coast, and in offshore waters off the
southeast coast of Stewart Island during January-March.
Southern Elephant Seal
The southern elephant seal has a near circumpolar distribution in
the Southern Hemisphere (Jefferson et al. 2015). However, the
distribution of southern elephant seals does not typically extend to
the proposed survey areas (NABIS 2017). Breeding colonies occur on some
New Zealand sub-Antarctic Islands, including Antipodes and Campbell
Islands (Suisted and Neale 2004); these are part of the Macquarie
Island stock of southern elephant seals (Taylor and Taylor 1989). Pups
are occasionally born during September-October on east coast beaches of
the mainland, including the southern coast of South Island (between
Oamaru and Nugget Point), Kaikoura Peninsula, and on the southeast
coast of North Island (Taylor and Taylor 1989; Harcourt 2001).
Even though mainland New Zealand is not part of their regular
distribution, juvenile southern elephant seals are sometimes seen over
the shelf of South Island (van den Hoff et al. 2002; Field et al.
2004); there are numerous sightings along the southeastern and
southwestern coasts of South Island in the marine mammal sightings and
strandings database (NZDOC 2017b). Most sightings occur during the
haul-out period in July and August and between November and January
during the molt (van den Hoff 2001). Sightings have been made on the
northeastern coast of South Island, including Kaikoura Peninsula
(Harcourt 2001; van den Hoff 2001; NZDOC 2017b). Individuals have also
occurred in the Bay of Plenty and Gisborne (Harcourt 2001); others have
been seen in Wellington and other North Island beaches (Daniel 1971),
and off Cape Palliser during the austral summer (NZDOC 2017b).
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
[[Page 45127]]
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 the exception for lower limits
for low-frequency cetaceans where the lower bound 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;
[ssquf] 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;
[ssquf] 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.
[ssquf] Pinnipeds in water; Phocidae (true seals): Generalized
hearing is estimated to occur between approximately 50 Hz to 86 kHz,
with best hearing between 1-50 kHz;
[ssquf] Pinnipeds in water; Otariidae (eared seals): Generalized
hearing is estimated to occur between 60 Hz and 39 kHz, with best
hearing between 2-48 kHz.
The pinniped functional hearing group was modified from Southall et
al. (2007) on the basis of data indicating that phocid species have
consistently demonstrated an extended frequency range of hearing
compared to otariids, especially in the higher frequency range
(Hemil[auml] et al., 2006; Kastelein et al., 2009; Reichmuth and Holt,
2013).
Table 3--Marine Functional Mammal Hearing Groups and Their Generalized
Hearing Ranges
------------------------------------------------------------------------
Hearing group Generalized hearing range *
------------------------------------------------------------------------
Low frequency (LF) cetaceans (baleen 7 Hz to 35 kHz.
whales).
Mid-frequency (MF) cetaceans (dolphins, 150 Hz to 160 kHz.
toothed whales, beaked whales,
bottlenose whales).
High-frequency (HF) cetaceans (true 275 Hz to 160 kHz.
porpoises, Kogia, river dolphins,
cephalorhynchid, Lagenorhynchus
cruciger and L. australis).
Phocid pinnipeds (PW) (underwater) (true 50 Hz to 86 kHz.
seals).
Otariid pinnipeds (OW) (underwater) (sea 60 Hz to 39 kHz.
lions and fur seals).
------------------------------------------------------------------------
* Represents the generalized hearing range for the entire group as a
composite (i.e., all species within the group), where individual
species' hearing ranges are typically not as broad. Generalized
hearing range chosen based on ~65 dB threshold from normalized
composite audiogram, with the exception for lower limits for LF
cetaceans (Southall et al., 2007) and PW pinniped (approximation).
For more detail concerning these groups and associated frequency
ranges, please see NMFS (2016) for a review of available information.
Thirty-eight marine mammal species have the reasonable potential to co-
occur with the proposed survey activities (Table 2). Of the cetacean
species that may be present, 9 are classified as low-frequency
cetaceans (i.e., all mysticete species), 21 are classified as mid-
frequency cetaceans (i.e., all delphinid and ziphiid species and the
sperm whale), and 4 are classified as high-frequency cetaceans (i.e.,
Kogia spp.). For the four pinniped species that may be present, 2 are
otariids and 2 are classified as phocids.
Potential Effects of Specified Activities on Marine Mammals and Their
Habitat
This section includes a summary and discussion of the ways that
components of the specified activity may impact marine mammals and
their habitat. The ``Estimated Take by Incidental Harassment'' 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, the ``Estimated Take by Incidental
Harassment'' 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.
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 the specified
activity and to a discussion of the potential effects of the specified
activity on marine mammals found later in this document.
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 decibel (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 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,
[[Page 45128]]
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 contained within a pulse and considers both
intensity and duration of exposure. Peak sound pressure (also referred
to as zero-to-peak sound pressure or 0-p) 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 or may radiate in all directions
(omnidirectional sources), as is the case for pulses produced by the
airgun arrays considered here. 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. Ambient
sound is defined as environmental background sound levels lacking a
single source or point (Richardson et al., 1995), and 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 the following
(Richardson et al., 1995):
Wind and waves: The complex interactions between wind and
water surface, including processes such as breaking waves and wave-
induced bubble oscillations and cavitation, are a main source of
naturally occurring ambient sound for frequencies between 200 Hz and 50
kHz (Mitson, 1995). In general, ambient sound levels tend to increase
with increasing wind speed and wave height. Surf sound becomes
important near shore, with measurements collected at a distance of 8.5
km from shore showing an increase of 10 dB in the 100 to 700 Hz band
during heavy surf conditions.
[ssquf] Precipitation: Sound from rain and hail impacting the water
surface can become an important component of total sound at frequencies
above 500 Hz, and possibly down to 100 Hz during quiet times.
[ssquf] Biological: 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.
[ssquf] Anthropogenic: Sources of ambient sound related to human
activity include transportation (surface vessels), dredging and
construction, oil and gas drilling and production, seismic surveys,
sonar, explosions, and ocean acoustic studies. 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. Sound from identifiable anthropogenic sources other than the
activity of interest (e.g., a passing vessel) is sometimes termed
background sound, as opposed to ambient sound.
The sum of the various natural and anthropogenic sound sources at
any given location and time--which comprise ``ambient'' or
``background'' sound--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 dB
from day to day (Richardson et al., 1995). The result is that,
depending on the source type and its intensity, sound from a given
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.
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 non-continuous (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 (such as
those used by the U.S. Navy). The duration of such sounds, as received
at a distance, can be greatly extended in a highly reverberant
environment.
Airgun arrays produce pulsed signals with energy in a frequency
range from about 10-2,000 Hz, with most energy radiated at frequencies
below 200 Hz. The amplitude of the acoustic wave emitted from the
source is equal in all directions (i.e., omnidirectional), but airgun
arrays do possess some directionality due to different phase delays
between guns in different directions. Airgun arrays are typically tuned
to maximize functionality for data acquisition purposes, meaning that
sound transmitted in horizontal directions and at higher frequencies is
minimized to the extent possible.
As described above, a Kongsberg EM 122 MBES, a Knudsen Chirp 3260
SBP, and a Teledyne RDI 75 kHz Ocean Surveyor ADCP would be operated
continuously during the proposed surveys, but not during transit to and
from the survey areas. Due to the lower
[[Page 45129]]
source level of the Kongsberg EM 122 MBES relative to the Langseth's
airgun array (242 dB re 1 [mu]Pa [middot] m for the MBES versus a
minimum of 249.4 dB re 1 [mu]Pa [middot] m (rms) for the 36 airgun
array and a minimum of 243.6 dB re 1 [mu]Pa [middot] m (rms) for the 18
airgun array) (NSF-USGS, 2011; Table 6), sounds from the MBES are
expected to be effectively subsumed by the sounds from the airgun
array. Thus, any marine mammal potentially exposed to sounds from the
MBES would already have been exposed to sounds from the airgun array,
which are expected to propagate further in the water. Each ping emitted
by the MBES consists of eight (in water >1,000 m deep) or four (<1,000
m) successive fan-shaped transmissions, each ensonifying a sector that
extends 1[deg] fore-aft. Given the movement and speed of the vessel,
the intermittent and narrow downward-directed nature of the sounds
emitted by the MBES would result in no more than one or two brief ping
exposures of any individual marine mammal, if any exposure were to
occur. Due to the lower source levels of both the Knudsen Chirp 3260
SBP and the Teledyne RDI 75 kHz Ocean Surveyor ADCP relative to the
Langseth's airgun array (maximum SL of 222 dB re 1 [mu]Pa [middot] m
for the SBP and maximum SL of 224 dB re 1 [mu]Pa [middot] m for the
ADCP, versus a minimum of 249.4 dB re 1 [mu]Pa [middot] m for the 36
airgun array and a minimum of 243.6 dB re 1 [mu]Pa [middot] m for the
18 airgun array) (NSF-USGS, 2011; Table 6 above), sounds from the SBP
and ADCP are expected to be effectively subsumed by sounds from the
airgun array. Thus, any marine mammal potentially exposed to sounds
from the SBP and/or the ADCP would already have been exposed to sounds
from the airgun array, which are expected to propagate further in the
water. As such, we conclude that the likelihood of marine mammal take
resulting from exposure to sound from the MBES, SBP or ADCP is
discountable and therefore we do not consider noise from the MBES, SBP
or ADCP further in this analysis.
Acoustic Effects
Here, we discuss the effects of active acoustic sources on marine
mammals.
Potential Effects of Underwater Sound--Please refer to the
information given previously (``Description of Active Acoustic
Sources'') regarding sound, characteristics of sound types, and metrics
used in this document. 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 the use of airgun arrays.
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 non-auditory physical or physiological
effects only briefly as we do not expect that use of the airgun arrays
is reasonably likely to result in such effects (see below for further
discussion). Potential effects from impulsive sound sources can range
in severity from effects such as behavioral disturbance or tactile
perception to physical discomfort, slight injury of the internal organs
and the auditory system, or mortality (Yelverton et al., 1973). 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; Tal et al., 2015). The
survey activities considered here do not involve the use of devices
such as explosives or mid-frequency tactical sonar that are associated
with these types of effects.
1. Threshold Shift--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). 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 airgun 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
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duration necessary to cause PTS as compared with TTS, it is
considerably less likely that PTS could occur.
For mid-frequency cetaceans in particular, potential protective
mechanisms may help limit onset of TTS or prevent onset of PTS. Such
mechanisms include dampening of hearing, auditory adaptation, or
behavioral amelioration (e.g., Nachtigall and Supin, 2013; Miller et
al., 2012; Finneran et al., 2015; Popov et al., 2016).
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.
Finneran et al. (2015) measured hearing thresholds in three captive
bottlenose dolphins before and after exposure to ten pulses produced by
a seismic airgun in order to study TTS induced after exposure to
multiple pulses. Exposures began at relatively low levels and gradually
increased over a period of several months, with the highest exposures
at peak SPLs from 196 to 210 dB and cumulative (unweighted) SELs from
193-195 dB. No substantial TTS was observed. In addition, behavioral
reactions were observed that indicated that animals can learn behaviors
that effectively mitigate noise exposures (although exposure patterns
must be learned, which is less likely in wild animals than for the
captive animals considered in this study). The authors note that the
failure to induce more significant auditory effects was likely due to
the intermittent nature of exposure, the relatively low peak pressure
produced by the acoustic source, and the low-frequency energy in airgun
pulses as compared with the frequency range of best sensitivity for
dolphins and other mid-frequency cetaceans.
Currently, TTS data only exist for four species of cetaceans
(bottlenose dolphin, beluga whale, harbor porpoise, and Yangtze finless
porpoise) exposed to a limited number of sound sources (i.e., mostly
tones and octave-band noise) in laboratory settings (Finneran, 2015).
In general, harbor porpoises have a lower TTS onset than other measured
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.
Critical questions remain regarding the rate of TTS growth and
recovery after exposure to intermittent noise and the effects of single
and multiple pulses. Data at present are also insufficient to construct
generalized models for recovery and determine the time necessary to
treat subsequent exposures as independent events. More information is
needed on the relationship between auditory evoked potential and
behavioral measures of TTS for various stimuli. 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).
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 acoustic source vessels with no apparent discomfort
or obvious behavioral change (e.g., Barkaszi et al., 2012).
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
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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; Ng and Leung, 2003; Nowacek et al.; 2004; Goldbogen et
al., 2013a, b). 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.
Visual tracking, passive acoustic monitoring, and movement
recording tags were used to quantify sperm whale behavior prior to,
during, and following exposure to airgun arrays at received levels in
the range 140-160 dB at distances of 7-13 km, following a phase-in of
sound intensity and full array exposures at 1-13 km (Madsen et al.,
2006; Miller et al., 2009). Sperm whales did not exhibit horizontal
avoidance behavior at the surface. However, foraging behavior may have
been affected. The sperm whales exhibited 19 percent less vocal (buzz)
rate during full exposure relative to post exposure, and the whale that
was approached most closely had an extended resting period and did not
resume foraging until the airguns had ceased firing. The remaining
whales continued to execute foraging dives throughout exposure;
however, swimming movements during foraging dives were 6 percent lower
during exposure than control periods (Miller et al., 2009). These data
raise concerns that seismic surveys may impact foraging behavior in
sperm whales, although more data are required to understand whether the
differences were due to exposure or natural variation in sperm whale
behavior (Miller et al., 2009).
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).
Cerchio et al. (2014) used passive acoustic monitoring to document
the presence of singing humpback whales off the coast of northern
Angola and to opportunistically test for the effect of seismic survey
activity on the number of singing whales. Two recording units were
deployed between March and December 2008 in the offshore environment;
numbers of singers were counted every hour. Generalized Additive Mixed
Models were used to assess the effect of survey day (seasonality), hour
(diel variation), moon phase, and received levels of noise (measured
from a single pulse during each ten minute sampled period) on singer
number. The number of singers significantly decreased with increasing
received level of noise, suggesting that humpback whale breeding
activity was disrupted to some extent by the survey activity.
Castellote et al. (2012) reported acoustic and behavioral changes
by fin whales in response to shipping and airgun noise. Acoustic
features of fin whale song notes recorded in the Mediterranean Sea and
northeast Atlantic Ocean were compared for areas with different
shipping noise levels and traffic intensities and during a seismic
airgun survey. During the first 72 h of the survey, a steady decrease
in song received levels and bearings to singers indicated that whales
moved away from the acoustic source and out of the study area. This
displacement persisted for a time period well beyond the 10-day
duration of seismic airgun activity, providing evidence that fin whales
may avoid an area for an extended period in the presence of increased
noise. The authors hypothesize that fin whale acoustic communication is
modified to compensate for increased background noise and that a
sensitization process may play a role in the observed temporary
displacement.
Seismic pulses at average received levels of 131 dB re 1
[micro]Pa\2\-s caused blue whales to increase call production (Di Iorio
and Clark, 2010). In contrast, McDonald et al. (1995) tracked a blue
whale with seafloor seismometers and reported that it stopped
vocalizing and changed its travel direction at a range of 10 km from
the acoustic source vessel (estimated received level 143 dB pk-pk).
Blackwell et al. (2013) found that bowhead whale call rates dropped
significantly at onset of airgun use at sites with a median distance of
41-45 km from the survey. Blackwell et al. (2015) expanded this
analysis to show that whales actually increased calling rates as soon
as airgun signals were detectable before ultimately decreasing calling
rates at higher received levels (i.e., 10-minute SELcum of
~127 dB). Overall, these results suggest that bowhead whales may adjust
their vocal output in an effort to compensate for noise before ceasing
vocalization effort
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and ultimately deflecting from the acoustic source (Blackwell et al.,
2013, 2015). These studies demonstrate that even low levels of noise
received far from the source can induce changes in vocalization and/or
behavior for mysticetes.
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 surveys (Malme et al.,
1984). Humpback whales showed avoidance behavior in the presence of an
active seismic array during observational studies and controlled
exposure experiments in western Australia (McCauley et al., 2000).
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., 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-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.
Stone (2015) reported data from at-sea observations during 1,196
seismic surveys from 1994 to 2010. When large arrays of airguns
(considered to be 500 in\3\ or more) were firing, lateral displacement,
more localized avoidance, or other changes in behavior were evident for
most odontocetes. However, significant responses to large arrays were
found only for the minke whale and fin whale. Behavioral responses
observed included changes in swimming or surfacing behavior, with
indications that cetaceans remained near the water surface at these
times. Cetaceans were recorded as feeding less often when large arrays
were active. Behavioral observations of gray whales during a seismic
survey monitored whale movements and respirations pre-, during and
post-seismic survey (Gailey et al., 2016). Behavioral state and water
depth were the best `natural' predictors of whale movements and
respiration and, after considering natural variation, none of the
response variables were significantly associated with seismic survey or
vessel sounds.
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
sufficiently 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
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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 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.
Other Potential Impacts
Here, we discuss potential effects of the proposed activity on
marine mammals other than sound.
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 (e.g., fin whales), which are
occasionally found draped across the bulbous bow of large commercial
ships upon arrival in port. Although smaller cetaceans 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) also 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 50 percent, while the probability asymptotically
increases toward one hundred percent above 15 kn.
The Langseth travels at a speed of ~8.3 km/hour while towing
seismic survey gear (LGL 2017). At this speed, 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 discountable. Ship strikes, as analyzed in the
studies cited above, generally involve commercial shipping, which is
much more common in both
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space and time than is geophysical survey 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 no
such incidents were reported for geophysical survey vessels 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. This
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, 2013b). 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
cetaceans 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 the vessel striking a marine mammal is
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 a seismic data
acquisition vessel towing gear, while not impossible, represent
unlikely, unpredictable events for which there are no preventive
measures. Given the required mitigation measures, the relatively slow
speed of the vessel towing gear, the presence of bridge crew watching
for obstacles at all times (including marine mammals), and the presence
of marine mammal observers, 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 the specified activity will
not be discussed further in the following analysis.
Stranding-- When a living or dead marine mammal swims or floats
onto shore and becomes ``beached'' or incapable of returning to sea,
the event is a ``stranding'' (Geraci et al., 1999; Perrin and Geraci,
2002; Geraci and Lounsbury, 2005; NMFS, 2007). The legal definition for
a stranding within the United States under the MMPA is that ``(A) a
marine mammal is dead and is (i) on a beach or shore of the United
States; or (ii) in waters under the jurisdiction of the United States
(including any navigable waters); or (B) a marine mammal is alive and
is (i) on a beach or shore of the United States and unable to return to
the water; (ii) on a beach or shore of the United States and, although
able to return to the water, is in need of apparent medical attention;
or (iii) in the waters under the jurisdiction of the United States
(including any navigable waters), but is unable to return to its
natural habitat under its own power or without assistance'' (16 U.S.C.
1421h(3)).
Marine mammals strand for a variety of reasons, such as infectious
agents, biotoxicosis, starvation, fishery interaction, ship strike,
unusual oceanographic or weather events, sound exposure, or
combinations of these stressors sustained concurrently or in series.
However, the cause or causes of most strandings are unknown (Geraci et
al., 1976; Eaton, 1979; Odell et al., 1980; Best, 1982). Numerous
studies suggest that the physiology, behavior, habitat relationships,
age, or condition of cetaceans may cause them to strand or might pre-
dispose them to strand when exposed to another phenomenon. These
suggestions are consistent with the conclusions of numerous other
studies that have demonstrated that combinations of dissimilar
stressors commonly combine to kill an animal or dramatically reduce its
fitness, even though one exposure without the other does not produce
the same result (Chroussos, 2000; Creel, 2005; DeVries et al., 2003;
Fair and Becker, 2000; Foley et al., 2001; Moberg, 2000; Relyea, 2005a;
2005b, Romero, 2004; Sih et al., 2004).
Use of military tactical sonar has been implicated in a majority of
investigated stranding events, although one stranding event was
associated with the use of seismic airguns. This event occurred in the
Gulf of California, coincident with seismic reflection profiling by the
R/V Maurice Ewing operated by Columbia University's Lamont-Doherty
Earth Observatory and involved two Cuvier's beaked whales (Hildebrand,
2004). The vessel had been firing an array of 20 airguns with a total
volume of 8,500 in\3\ (Hildebrand, 2004; Taylor et al., 2004). Most
known stranding events have involved beaked whales, though a small
number have involved deep-diving delphinids or sperm whales (e.g.,
Mazzariol et al., 2010; Southall et al., 2013). In general, long
duration (~1 second) and high-intensity sounds (>235 dB SPL) have been
implicated in stranding events (Hildebrand, 2004). With regard to
beaked whales, mid-frequency sound is typically implicated (when
causation can be determined) (Hildebrand, 2004). Although seismic
airguns create predominantly low-frequency energy, the signal does
include a mid-frequency component. We have considered the potential for
the proposed survey to result in marine mammal stranding and have
concluded that, based on the best available information, stranding is
not expected to occur.
Entanglement and discharges--We are not aware of any records of
marine mammal entanglement in towed arrays such as those considered
here. The discharge of trash and debris is prohibited (33 CFR 151.51-
77) unless it is passed through a machine that breaks up solids such
that they can pass through a 25-mm mesh screen. All other trash and
debris must be returned to shore for proper disposal with municipal and
solid waste. Some personal items may be accidentally lost overboard.
However, U.S. Coast Guard and Environmental Protection Act regulations
require operators to become proactive in avoiding accidental loss of
solid waste items by developing waste management plans, posting
informational placards, manifesting trash sent to shore, and using
special precautions such as covering outside trash bins to prevent
accidental loss of solid waste. There are no meaningful entanglement
risks posed by the described activity, and entanglement risks are not
discussed further in this document.
Marine mammals could be affected by accidentally spilled diesel
fuel from a vessel associated with proposed survey activities.
Quantities of diesel fuel on the sea surface may affect marine mammals
through various pathways: Surface contact of the fuel with skin and
other mucous membranes, inhalation of concentrated petroleum vapors, or
ingestion of the fuel (direct ingestion or by the ingestion of oiled
prey) (e.g., Geraci and St. Aubin, 1980, 1985, 1990). However, the
likelihood of a fuel spill during any particular geophysical survey is
considered to be remote, and the potential for impacts to marine
mammals would depend greatly on the
[[Page 45135]]
size and location of a spill and meteorological conditions at the time
of the spill. Spilled fuel would rapidly spread to a layer of varying
thickness and break up into narrow bands or windrows parallel to the
wind direction. The rate at which the fuel spreads would be determined
by the prevailing conditions such as temperature, water currents, tidal
streams, and wind speeds. Lighter, volatile components of the fuel
would evaporate to the atmosphere almost completely in a few days.
Evaporation rate may increase as the fuel spreads because of the
increased surface area of the slick. Rougher seas, high wind speeds,
and high temperatures also tend to increase the rate of evaporation and
the proportion of fuel lost by this process (Scholz et al., 1999). We
do not anticipate potentially meaningful effects to marine mammals as a
result of any contaminant spill resulting from the proposed survey
activities, and contaminant spills are not discussed further in this
document.
Anticipated Effects on Marine Mammal Habitat
Effects to Prey--Marine mammal prey varies by species, season, and
location and, for some, is not well documented. Fish react to sounds
which are especially strong and/or intermittent low-frequency sounds.
Short duration, sharp sounds can cause overt or subtle changes in fish
behavior and local distribution. Hastings and Popper (2005) identified
several studies that suggest fish may relocate to avoid certain areas
of sound energy. Additional studies have documented effects of pulsed
sound on fish, although several are based on studies in support of
construction projects (e.g., Scholik and Yan, 2001, 2002; Popper and
Hastings, 2009). Sound pulses at received levels of 160 dB may cause
subtle changes in fish behavior. SPLs of 180 dB may cause noticeable
changes in behavior (Pearson et al., 1992; Skalski et al., 1992). SPLs
of sufficient strength have been known to cause injury to fish and fish
mortality. The most likely impact to fish from survey activities at the
project area would be temporary avoidance of the area. The duration of
fish avoidance of a given area after survey effort stops is unknown,
but a rapid return to normal recruitment, distribution and behavior is
anticipated.
Information on seismic airgun impacts to zooplankton, which
represent an important prey type for mysticetes, is limited. However,
McCauley et al. (2017) reported that experimental exposure to a pulse
from a 150 inch\3\ airgun decreased zooplankton abundance when compared
with controls, as measured by sonar and net tows, and caused a two- to
threefold increase in dead adult and larval zooplankton. Although no
adult krill were present, the study found that all larval krill were
killed after air gun passage. Impacts were observed out to the maximum
1.2 km range sampled.
In general, impacts to marine mammal prey are expected to be
limited due to the relatively small temporal and spatial overlap
between the proposed survey and any areas used by marine mammal prey
species. The proposed survey would occur over a relatively short time
period (90 days) and would occur over a very small area relative to the
area available as marine mammal habitat in the Pacific Ocean off New
Zealand. We do not have any information to suggest the proposed survey
area represents a significant feeding area for any marine mammal, and
we believe any impacts to marine mammals due to adverse affects to
their prey would be insignificant due to the limited spatial and
temporal impact of the proposed survey. However, adverse impacts may
occur to a few species of fish and to zooplankton.
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 use of airgun arrays). 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 see also the previous discussion on
masking under ``Acoustic Effects''), 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). Although the signals emitted by
seismic airgun arrays are generally low frequency, they would also
likely be of short duration and transient in any given area due to the
nature of these surveys. As described previously, exploratory surveys
such as these cover a large area but would be transient rather than
focused in a given location over time and therefore would not be
considered chronic in any given location.
In summary, activities associated with the proposed action are not
likely to have a permanent, adverse effect on any fish habitat or
populations of fish species or on the quality of acoustic habitat.
Thus, any impacts to marine mammal habitat are not expected to cause
significant or long-term consequences for individual marine mammals or
their populations.
Estimated Take
This section provides an estimate of the number of incidental takes
proposed for authorization through this IHA, which will inform both
NMFS' consideration of whether the number of takes is ``small'' and the
negligible impact determination.
Harassment is the only type of take expected to result from these
activities. 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).
Authorized takes would primarily be by Level B harassment, as use
of the seismic airguns have the potential to result in disruption of
behavioral patterns for individual marine
[[Page 45136]]
mammals. There is also some potential for auditory injury (Level A
harassment) to result, primarily for mysticetes and high frequency
cetaceans (i.e., kogiidae spp.), due to larger predicted auditory
injury zones for those functional hearing groups. Auditory injury is
unlikely to occur for mid-frequency species given very small modeled
zones of injury for those species. The proposed mitigation and
monitoring measures are expected to minimize the severity of such
taking to the extent practicable.
As described previously, no serious injury or mortality is
anticipated or proposed to be authorized for this activity. Below we
describe how the take is estimated.
Described in the most basic way, we estimate take by considering:
(1) acoustic thresholds above which NMFS believes the best available
science indicates marine mammals will be behaviorally harassed or incur
some degree of permanent hearing impairment; (2) the area or volume of
water that will be ensonified above these levels in a day; (3) the
density or occurrence of marine mammals within these ensonified areas;
and (4) and the number of days of activities. Below, we describe these
components in more detail and present the exposure estimate and
associated numbers of take proposed for authorization.
Acoustic Thresholds
Using the best available science, NMFS has developed acoustic
thresholds that identify the received level of underwater sound above
which exposed marine mammals would be reasonably expected to be
behaviorally harassed (equated to Level B harassment) or to incur PTS
of some degree (equated to Level A harassment).
Level B Harassment for non-explosive sources-- Though significantly
driven by received level, the onset of behavioral disturbance from
anthropogenic noise exposure is also informed to varying degrees by
other factors related to the source (e.g., frequency, predictability,
duty cycle), the environment (e.g., bathymetry), and the receiving
animals (hearing, motivation, experience, demography, behavioral
context) and can be difficult to predict (Southall et al., 2007,
Ellison et al. 2011). Based on the best available science and the
practical need to use a threshold based on a factor that is both
predictable and measurable for most activities, NMFS uses a generalized
acoustic threshold based on received level to estimate the onset of
behavioral harassment. NMFS predicts that marine mammals are likely to
be behaviorally harassed in a manner we consider to fall under Level B
harassment when exposed to underwater anthropogenic noise above
received levels of 120 dB re 1 [mu]Pa (rms) for continuous sources
(e.g. vibratory pile-driving, drilling) and above 160 dB re 1 [mu]Pa
(rms) for non-explosive impulsive (e.g., seismic airguns) or
intermittent (e.g., scientific sonar) sources. L-DEO's proposed
activity includes the use of impulsive seismic sources. Therefore, the
160 dB re 1 [mu]Pa (rms) criteria is applicable for analysis of level B
harassment.
Level A harassment for non-explosive sources--NMFS' Technical
Guidance for Assessing the Effects of Anthropogenic Sound on Marine
Mammal Hearing (NMFS, 2016) identifies dual criteria to assess auditory
injury (Level A harassment) to five different marine mammal groups
(based on hearing sensitivity) as a result of exposure to noise from
two different types of sources (impulsive or non-impulsive). The
Technical Guidance identifies the received levels, or thresholds, above
which individual marine mammals are predicted to experience changes in
their hearing sensitivity for all underwater anthropogenic sound
sources, reflects the best available science, and better predicts the
potential for auditory injury than does NMFS' historical criteria.
These thresholds were developed by compiling and synthesizing the
best available science and soliciting input multiple times from both
the public and peer reviewers to inform the final product, and are
provided in Table 4 below. The references, analysis, and methodology
used in the development of the thresholds are described in NMFS 2016
Technical Guidance, which may be accessed at: http://www.nmfs.noaa.gov/pr/acoustics/guidelines.htm. As described above, L-DEO's proposed
activity includes the use of intermittent and impulsive seismic
sources.
Table 4--Thresholds Identifying the Onset of Permanent Threshold Shift
in Marine Mammals
------------------------------------------------------------------------
PTS onset thresholds
Hearing group ---------------------------------------
Impulsive * Non-impulsive
------------------------------------------------------------------------
Low-Frequency (LF) Cetaceans.... Lpk,flat: 219 dB, LE,LF,24h: 199 dB.
LE,LF,24h: 183 dB.
Mid-Frequency (MF) Cetaceans.... Lpk,flat: 230 dB, LE,MF,24h: 198 dB.
LE,MF,24h: 185 dB.
High-Frequency (HF) Cetaceans... Lpk,flat: 202 dB, LE,HF,24h: 173 dB.
LE,HF,24h: 155 dB.
Phocid Pinnipeds (PW) Lpk,flat: 218 dB, LE,PW,24h: 201 dB.
(Underwater). LE,PW,24h: 185 dB.
Otariid Pinnipeds (OW) Lpk,flat: 232 dB, LE,OW,24h: 219 dB.
(Underwater). LE,OW,24h: 203 dB.
------------------------------------------------------------------------
Note: *Dual metric acoustic thresholds for impulsive sounds: Use
whichever results in the largest isopleth for calculating PTS onset.
If a non-impulsive sound has the potential of exceeding the peak sound
pressure level thresholds associated with impulsive sounds, these
thresholds should also be considered.
Note: Peak sound pressure (Lpk) has a reference value of 1 [mu]Pa, and
cumulative sound exposure level (LE) has a reference value of
1[mu]Pa2s. In this Table, thresholds are abbreviated to reflect
American National Standards Institute standards (ANSI 2013). However,
peak sound pressure is defined by ANSI as incorporating frequency
weighting, which is not the intent for this Technical Guidance. Hence,
the subscript ``flat'' is being included to indicate peak sound
pressure should be flat weighted or unweighted within the generalized
hearing range. The subscript associated with cumulative sound exposure
level thresholds indicates the designated marine mammal auditory
weighting function (LF, MF, and HF cetaceans, and PW and OW pinnipeds)
and that the recommended accumulation period is 24 hours. The
cumulative sound exposure level thresholds could be exceeded in a
multitude of ways (i.e., varying exposure levels and durations, duty
cycle). When possible, it is valuable for action proponents to
indicate the conditions under which these acoustic thresholds will be
exceeded.
Ensonified Area
Here, we describe operational and environmental parameters of the
activity that will feed into estimating the area ensonified above the
relevant acoustic thresholds.
The proposed survey would entail use of a 36-airgun array with a
total discharge of 6,600 in\3\ at a tow depth of 9 m and an 18-airgun
array with a total discharge of 3,300 in\3\ at a tow depth of 7-9 m.
Received sound levels were predicted by L-DEO's model (Diebold et al.,
2010) as a function of distance from the 36-airgun array and 18-airgun
array and for a single 40-in\3\ airgun which would be used during power
downs; all models used a 9 m tow depth. This
[[Page 45137]]
modeling approach uses ray tracing for the direct wave traveling from
the array to the receiver and its associated source ghost (reflection
at the air-water interface in the vicinity of the array), in a
constant-velocity half-space (infinite homogeneous ocean layer,
unbounded by a seafloor). In addition, propagation measurements of
pulses from the 36-airgun array at a tow depth of 6 m have been
reported in deep water (approximately 1600 m), intermediate water depth
on the slope (approximately 600-1100 m), and shallow water
(approximately 50 m) in the Gulf of Mexico in 2007-2008 (Tolstoy et al.
2009; Diebold et al. 2010).
For deep and intermediate-water cases, L-DEO determined that the
field measurements cannot be used readily to derive mitigation radii,
as at those sites the calibration hydrophone was located at a roughly
constant depth of 350-500 m, which may not intersect all the SPL
isopleths at their widest point from the sea surface down to the
maximum relevant water depth for marine mammals of approximately 2,000
m (See Appendix H in NSF-USGS 2011). At short ranges, where the direct
arrivals dominate and the effects of seafloor interactions are minimal,
the data recorded at the deep and slope sites are suitable for
comparison with modeled levels at the depth of the calibration
hydrophone. At longer ranges, the comparison with the mitigation
model--constructed from the maximum SPL through the entire water column
at varying distances from the airgun array--is the most relevant.
Please see the IHA application for further discussion of summarized
results.
For deep water (>1000 m), L-DEO used the deep-water radii obtained
from model results down to a maximum water depth of 2000 m. The radii
for intermediate water depths (100-1000 m) were derived from the deep-
water ones by applying a correction factor (multiplication) of 1.5,
such that observed levels at very near offsets fall below the corrected
mitigation curve (See Fig. 16 in Appendix H of NSF-USGS, 2011). The
shallow-water radii were obtained by scaling the empirically derived
measurements from the Gulf of Mexico calibration survey to account for
the differences in tow depth between the calibration survey (6 m) and
the proposed surveys (9 m). A simple scaling factor is calculated from
the ratios of the isopleths determined by the deep-water L-DEO model,
which are essentially a measure of the energy radiated by the source
array.
Measurements have not been reported for the single 40-in\3\ airgun.
L-DEO model results are used to determine the 160-dB (rms) radius for
the 40-in\3\ airgun at a 9 m tow depth in deep water (See LGL 2017,
Figure 6). For intermediate-water depths, a correction factor of 1.5
was applied to the deep-water model results. For shallow water, a
scaling of the field measurements obtained for the 36-airgun array was
used.
L-DEO's modeling methodology is described in greater detail in the
IHA application (LGL 2017) and we refer the reader to that document
rather than repeating it here. The estimated distances to the Level B
harassment isopleth for the Langseth's 36-airgun array, 18-airgun
array, and the single 40-in\3\ airgun are shown in Table 5.
Table 5--Predicted Radial Distances From R/V Langseth Seismic Source to
Isopleths Corresponding to Level B Harassment Threshold
------------------------------------------------------------------------
Predicted distance
Source and volume Water depth to threshold (160
dB re 1 [mu]Pa) \1\
------------------------------------------------------------------------
1 airgun, 40 in\3\............. >1000 m........... 388 m.
100-1000 m........ 582 m.
<100 m............ 938 m.
18 airguns, 3,300 in\3\........ >1000 m........... 3,562 m.
100-1000 m........ 5,343 m.
<100 m............ 10,607 m.
36 airguns, 6,600 in\3\........ >1000 m........... 5,629 m.
100-1000 m........ 8,444 m.
<100 m............ 22,102 m.
------------------------------------------------------------------------
\1\ Distances for depths >1000 m are based on L-DEO model results.
Distance for depths 100-1000 m are based on L-DEO model results with a
1.5 x correction factor between deep and intermediate water depths.
Distances for depths <100 m are based on empirically derived
measurements in the Gulf of Mexico with scaling applied to account for
differences in tow depth.
Predicted distances to Level A harassment isopleths, which vary
based on marine mammal hearing groups (Table 3), were calculated based
on modeling performed by L-DEO using the NUCLEUS software program and
the NMFS User Spreadsheet, described below. The updated acoustic
thresholds for impulsive sounds (e.g., airguns) contained in the
Technical Guidance were presented as dual metric acoustic thresholds
using both SELcum and peak sound pressure metrics (NMFS
2016). As dual metrics, NMFS considers onset of PTS (Level A
harassment) to have occurred when either one of the two metrics is
exceeded (i.e., metric resulting in the largest isopleth). The
SELcum metric considers both level and duration of exposure,
as well as auditory weighting functions by marine mammal hearing group.
In recognition of the fact that the requirement to calculate Level A
harassment ensonified areas could be more technically challenging to
predict due to the duration component and the use of weighting
functions in the new SELcum thresholds, NMFS developed an
optional User Spreadsheet that includes tools to help predict a simple
isopleth that can be used in conjunction with marine mammal density or
occurrence to facilitate the estimation of take numbers.
The values for SELcum and peak SPL for the Langseth
airgun array were derived from calculating the modified farfield
signature (Table 6). The farfield signature is often used as a
theoretical representation of the source level. To compute the farfield
signature, the source level is estimated at a large distance below the
array (e.g., 9 km), and this level is back projected mathematically to
a notional distance of 1 m from the array's geometrical center.
However, when the source is an array of multiple airguns separated in
space, the source level from the theoretical farfield signature is not
necessarily the best measurement of the source level that is physically
achieved at the source (Tolstoy et al. 2009). Near the source (at short
ranges, distances <1 km), the pulses of sound pressure from each
individual airgun in the source array do not stack constructively, as
they do for the theoretical farfield signature. The pulses from the
different airguns spread out in time such that the source levels
observed or modeled are the result of the summation of pulses from a
few airguns, not the full array (Tolstoy et al. 2009). At larger
distances, away from the source array center, sound pressure of all the
airguns in the array stack coherently, but not within one time sample,
resulting in smaller source levels (a few dB) than the source level
derived from the farfield signature. Because the farfield signature
does not take into account the large array effect near the source and
is calculated as a point source, the modified farfield signature is a
more appropriate measure of the sound source level for distributed
sound sources, such as airgun arrays. L-DEO used the acoustic modeling
methodology as used for Level B takes with a small grid step of 1 m in
both the inline and depth directions. The propagation modeling takes
into account all airgun interactions at short distances from the
source, including interactions between subarrays which are modeled
using the NUCLEUS software to estimate the notional signature and
MATLAB software to
[[Page 45138]]
calculate the pressure signal at each mesh point of a grid.
Table 6--Modeled source levels based on modified farfield signature for the R/V Langseth 6,600 in\3\ airgun
array, 3,300 in\3\ airgun array, and single 40 in\3\ airgun
----------------------------------------------------------------------------------------------------------------
High Phocid Otariid
Low frequency Mid frequency frequency Pinnipeds Pinnipeds
cetaceans cetaceans cetaceans (Underwater) (Underwater)
(Lpk,flat: 219 (Lpk,flat: 230 (Lpk,flat: 202 (Lpk,flat: 218 (Lpk,flat: 232
dB; dB; dB; dB; dB;
LE,LF,24h: 183 LE,MF,24h: 185 LE,HF,24h: 155 LE,HF,24h: 185 LE,HF,24h: 203
dB) dB dB) dB) dB)
----------------------------------------------------------------------------------------------------------------
6,600 in\3\ airgun array (Peak 250.77 252.76 249.44 250.50 252.72
SPLflat).......................
6,600 in\3\ airgun array 232.75 232.67 232.83 232.67 231.07
(SELcum).......................
3,300 in\3\ airgun array (Peak 246.34 250.98 243.64 246.03 251.92
SPLflat).......................
3,300 in\3\ airgun array 226.22 226.13 226.75 226.13 226.89
(SELcum).......................
40 in\3\ airgun (Peak SPLflat).. 224.02 225.16 224.00 224.09 226.64
40 in\3\ airgun (SELcum)........ 202.33 202.35 203.12 202.35 202.61
----------------------------------------------------------------------------------------------------------------
In order to more realistically incorporate the Technical Guidance's
weighting functions over the seismic array's full acoustic band,
unweighted spectrum data for the Langseth's airgun array (modeled in 1
Hz bands) was used to make adjustments (dB) to the unweighted spectrum
levels, by frequency, according to the weighting functions for each
relevant marine mammal hearing group. These adjusted/weighted spectrum
levels were then converted to pressures (micropascals) in order to
integrate them over the entire broadband spectrum, resulting in
broadband weighted source levels by hearing group that could be
directly incorporated within the User Spreadsheet (i.e., to override
the Spreadsheet's more simple weighting factor adjustment). Using the
User Spreadsheet's ``safe distance'' methodology for mobile sources
(described by Sivle et al., 2014) with the hearing group-specific
weighted source levels, and inputs assuming spherical spreading
propagation and source velocities and shot intervals specific to each
of the three proposed surveys (Table 1), potential radial distances to
auditory injury zones were then calculated for SELcum
thresholds.
Inputs to the User Spreadsheets in the form of estimated SLs are
shown in Table 6. User Spreadsheets used by L-DEO to estimate distances
to Level A harassment isopleths (SELcum) for the 36-airgun
array, 18-airgun array, and the single 40 in\3\ airgun for the South
Island 2-D survey, North Island 2-D survey, and North Island 3-D survey
are shown in Tables 3, 4, 7, 10, 11, and 12, of the IHA application
(LGL 2017). Outputs from the User Spreadsheets in the form of estimated
distances to Level A harassment isopleths for the South Island 2-D
survey, North Island 2-D survey, and North Island 3-D survey are shown
in Tables 7, 8 and 9, respectively. As described above, NMFS considers
onset of PTS (Level A harassment) to have occurred when either one of
the dual metrics (SELcum and Peak SPLflat) is
exceeded (i.e., metric resulting in the largest isopleth).
Table 7--Modeled Radial Distances (m) to Isopleths Corresponding to Level A Harassment Thresholds During
Proposed North Island 2-D Survey
----------------------------------------------------------------------------------------------------------------
High Phocid Otariid
Low frequency Mid frequency frequency Pinnipeds Pinnipeds
cetaceans cetaceans cetaceans (Underwater) (Underwater)
(Lpk,flat: 219 (Lpk,flat: 230 (Lpk,flat: 202 (Lpk,flat: 218 (Lpk,flat: 232
dB; dB; dB; dB; dB;
LE,LF,24h: 183 LE,MF,24h: 185 LE,HF,24h: 155 LE,HF,24h: 185 LE,HF,24h: 203
dB) dB dB) dB) dB)
----------------------------------------------------------------------------------------------------------------
6,600 in\3\ airgun array (Peak 38.8 13.8 229.2 42.2 10.9
SPLflat).......................
6,600 in\3\ airgun array 501.3 0 1.2 13.2 0
(SELcum).......................
40 in\3\ airgun (Peak SPLflat).. 1.8 0.6 12.6 2.0 0.5
40 in\3\ airgun (SELcum)........ 0.4 0 0 0 0
----------------------------------------------------------------------------------------------------------------
Table 8--Modeled Radial Distances (m) to Isopleths Corresponding to Level A Harassment Thresholds During
Proposed North Island 3-D Survey
----------------------------------------------------------------------------------------------------------------
High Phocid Otariid
Low frequency Mid frequency frequency Pinnipeds Pinnipeds
cetaceans cetaceans cetaceans (Underwater) (Underwater)
(Lpk,flat: 219 (Lpk,flat: 230 (Lpk,flat: 202 (Lpk,flat: 218 (Lpk,flat: 232
dB; dB; dB; dB; dB;
LE,LF,24h: 183 LE,MF,24h: 185 LE,HF,24h: 155 LE,HF,24h: 185 LE,HF,24h: 203
dB) dB dB) dB) dB)
----------------------------------------------------------------------------------------------------------------
3,300 in\3\ airgun array (Peak 23.3 11.2 119.0 25.2 9.9
SPLflat).......................
3,300 in\3\ airgun array 73.1 0 0.3 2.8 0
(SELcum).......................
40 in\3\ airgun (Peak SPLflat).. 1.8 0.6 12.6 2.0 0.5
40 in\3\ airgun (SELcum)........ 0.4 0 0 0 0
----------------------------------------------------------------------------------------------------------------
[[Page 45139]]
Table 9--Modeled Radial Distances (m) to Isopleths Corresponding to Level A Harassment Thresholds During
Proposed South Island 2-D Survey
----------------------------------------------------------------------------------------------------------------
High Phocid Otariid
Low frequency Mid frequency frequency Pinnipeds Pinnipeds
cetaceans cetaceans cetaceans (Underwater) (Underwater)
(Lpk,flat: 219 (Lpk,flat: 230 (Lpk,flat: 202 (Lpk,flat: 218 (Lpk,flat: 232
dB; dB; dB; dB; dB;
LE,LF,24h: 183 LE,MF,24h: 185 LE,HF,24h: 155 LE,HF,24h: 185 LE,HF,24h: 203
dB) dB dB) dB) dB)
----------------------------------------------------------------------------------------------------------------
6,600 in\3\ airgun array (Peak 38.8 13.8 229.2 42.2 10.9
SPLflat).......................
6,600 in\3\ airgun array 376.0 0 0.9 9.9 0
(SELcum).......................
40 in\3\ airgun (Peak SPLflat).. 1.8 0.6 12.6 2.0 0.5
40 in\3\ airgun (SELcum)........ 0.3 0 0 0 0
----------------------------------------------------------------------------------------------------------------
Note that because of some of the assumptions included in the
methods used, isopleths produced may be overestimates to some degree,
which will ultimately result in some degree of overestimate of Level A
take. However, these tools offer the best way to predict appropriate
isopleths when more sophisticated 3D modeling methods are not
available, and NMFS continues to develop ways to quantitatively refine
these tools and will qualitatively address the output where
appropriate. For mobile sources, such as the proposed seismic survey,
the User Spreadsheet predicts the closest distance at which a
stationary animal would not incur PTS if the sound source traveled by
the animal in a straight line at a constant speed.
Marine Mammal Occurrence
In this section we provide the information about the presence,
density, or group dynamics of marine mammals that will inform the take
calculations. The best available scientific information was considered
in conducting marine mammal exposure estimates (the basis for
estimating take).
No systematic aircraft- or ship-based surveys have been conducted
for marine mammals in offshore waters of the South Pacific Ocean off
New Zealand that can be used to estimate species densities that we are
aware of, with the exception of Hector's dolphin surveys that have
occurred off the South Island. Densities for Hector's dolphins off the
South Island were estimated using averaged estimated summer densities
from the most southern stratum of an East Coast South Island survey
(Otago) and a West Coast South Island survey (Milford Sound), both in
three offshore strata categories (0-4 nm, 4-12 nm, and 12-20 nm;
MacKenzie and Clement 2014, 2016). The estimated density for Hector's
dolphins for the South Island 2-D survey was based on the proportion of
that survey occurring in each offshore stratum.
For cetacean species other than Hector's dolphin, densities were
derived from data available for the Southern Ocean (Butterworth et al.
1994; Kasamatsu and Joyce 1995) (See Table 17 in the IHA application).
Butterworth et al. (1994) provided comparable data for sei, fin, blue,
and sperm whales extrapolated to latitudes 30-40[deg] S., 40-50[deg]
S., and 50-60[deg] S. based on Japanese scouting vessel data from 1965/
66-1977/78 and 1978/79-1987/88. Densities were calculated for these
species based on abundances and surface areas provided in Butterworth
et al. (1994) using the mean density for the more recent surveys (1978/
79-1987/88) and the 30-40[deg] S. and 40-50[deg] S. strata, because the
proposed survey areas are between ~37[deg] S. and 50[deg] S. Densities
were corrected for mean trackline detection probability, g(0)
availability bias, using mean g(0) values provided for these species
during NMFS Southwest Fisheries Science Center ship-based surveys
between 1991-2014 (Barlow 2016). Data for the humpback whale was also
presented in Butterworth et al. (1994), but, based on the best
available information, it was determined that the density values
presented for humpback whales in Butterworth et al. (1994) were likely
lower than would be expected in the proposed survey areas, thus the
density for humpback whales was ultimately calculated in the same way
as for the baleen whales for which density data was unavailable.
Kasamatsu and Joyce (1995) provided data for beaked whales, killer
whales, long-finned pilot whales, and Hourglass dolphins, based on
surveys conducted as part of the International Whaling Commission/
International Decade of Cetacean Research-Southern Hemisphere Minke
Whale Assessment, started in 1978/79, and the Japanese sightings survey
program started in 1976/77. Densities for these species were calculated
based on abundances and surface areas provided in Kasamatsu and Joyce
(1995) for Antarctic Areas V EMN and VI WM, which represent the two
areas reported in Kasamatsu and Joyce (1995) that are nearest to the
proposed South Island survey area. Densities were corrected for
availability bias using mean g(0) values provided by Kasamatsu and
Joyce (1995) for beaked whales, killer whales, and long-fined pilot
whales, and provided by Barlow (2016) for the Hourglass dolphin using
the mean g(0) calculated for unidentified dolphins during NMFS
Southwest Fisheries Science Center ship-based surveys between 1991-
2014.
For the remaining cetacean species, the relative abundances of
individual species expected to occur in the survey areas were estimated
within species groups. The relative abundances of these species were
estimated based on several factors, including information on marine
mammal observations from areas near the proposed survey areas (e.g.,
monitoring reports from previous IHAs (NMFS, 2015); datasets of
opportunistic sightings (Torres et al., 2014); and analyses of observer
data from other marine geophysical surveys conducted in New Zealand
waters (Blue Planet, 2016)), information on latitudinal ranges and
group sizes of marine mammals in New Zealand waters (e.g., Jefferson et
al., 2015; NABIS, 2017; Perrin et al., 2009), and other information on
marine mammals in and near the proposed survey areas (e.g., data on
marine mammal bycatch in New Zealand fisheries (Berkenbush et al.,
2013), data on marine mammal strandings (New Zealand Marine Mammal
Strandings and Sightings Database); and input from subject matter
experts (pers. comm., E. Slooten, Univ. of Otago, to H. Goldstein,
NMFS, April 11, 2015)).
For each species group (i.e., mysticetes), densities of species for
which data were available were averaged to get a mean density for the
group (e.g., densities of fin, sei, and blue whale were averaged to get
a mean density for mysticetes). Relative abundances of those species
were then averaged to get a mean relative
[[Page 45140]]
abundances (e.g., relative abundance of fin, sei, and blue whale were
averaged to get a mean relative abundance for mysticetes). For the
species for which density data was unavailable, their relative
abundance score was multiplied by the mean density of their respective
species group (i.e., relative abundance of minke whale was multiplied
by mean density for mysticetes). The product was then divided by the
mean relative abundance of the species group to come up with a density
estimate. The fin, sei, and blue whale densities calculated from
Butterworth et al. (1994) were proportionally averaged and used to
estimate the densities of the remaining mysticetes. The sperm whale
density calculated from Butterworth et al. (1994) was used to estimate
the density of the other Physeteridae species, the pygmy sperm whale.
The Hourglass dolphin, killer whale, and long-finned pilot whale
densities calculated from Kasamatsu and Joyce (1995) were
proportionally averaged and used to estimate the densities of the other
Delphinidae for which density data was not available. For beaked
whales, the beaked whale density calculated from Kasamatsu and Joyce
(1995) was proportionally allocated according to each beaked whale
species' estimated relative abundance value.
We are not aware of any information regarding at-sea densities of
pinnipeds off New Zealand. As such, a surrogate species (northern fur
seal) was used to estimate offshore pinniped densities for the proposed
surveys. The at-sea density of northern fur seals reported in Bonnell
et al. (1992), based on systematic aerial surveys conducted in 1989-
1990 in offshore areas off the west coast of the U.S., was used to
estimate the numbers of pinnipeds that might be present off New
Zealand. The northern fur seal density reported in Bonnell et al.
(1992) was used as the New Zealand fur seal density. Densities for the
other three pinniped species expected to occur in the proposed survey
areas were proportionally allocated relative to the value of the
density of the northern fur seal, in accordance to the estimated
relative abundance value of each of the other pinniped species.
NMFS acknowledges there is some uncertainty related to the
estimated density data and the assumptions used in their calculations.
Given the lack of available data on marine mammal density in the
proposed survey areas, the approach used is based on the best available
data. In recognition of the uncertainties in the density data, we have
proposed an additional 25 percent contingency in take estimates to
account for the fact that density estimates used to estimate take may
be underestimates of actual densities of marine mammals in the survey
area.
Take Calculation and Estimation
Here we describe how the information provided above is brought
together to produce a quantitative take estimate. In order to estimate
the number of marine mammals predicted to be exposed to sound levels
that would result in Level A harassment or Level B harassment, radial
distances from the airgun array to predicted isopleths corresponding to
the Level A harassment and Level B harassment thresholds are
calculated, as described above. Those radial distances are then used to
calculate the area(s) around the airgun array predicted to be
ensonified to sound levels that exceed the Level A harassment and Level
B harassment thresholds. The area estimated to be ensonified in a
single day of the survey is then calculated (Table 10), based on the
areas predicted to be ensonified around the array and the estimated
trackline distance traveled per day. This number is then multiplied by
the number of survey days (i.e., 35 days for the North Island 2-D
survey, 33 days for the North Island 3-D survey, and 22 days for the
South Island 2-D survey). The product is then multiplied by 1.5 to
account for an additional 25 percent contingency for potential
additional seismic operations (associated with turns, airgun testing,
and repeat coverage of any areas where initial data quality is sub-
standard, as proposed by L-DEO) and an additional 25 percent
contingency in acknowledgement of uncertainties in available density
estimates, as described above. This results in an estimate of the total
areas (km\2\) expected to be ensonified to the Level A harassment and
Level B harassment thresholds. For purposes of Level B take
calculations, areas estimated to be ensonified to Level A harassment
thresholds are subtracted from total areas estimated to be ensonified
to Level B harassment thresholds in order to avoid double counting the
animals taken (i.e., if an animal is taken by Level A harassment, it is
not also counted as taken by Level B harassment). The marine mammals
predicted to occur within these respective areas, based on estimated
densities, are assumed to be incidentally taken.
Table 10--Areas (km\2\) Estimated To Be Ensonified to Level A and Level B Harassment Thresholds Per Day for Three Proposed Seismic Surveys off New
Zealand
--------------------------------------------------------------------------------------------------------------------------------------------------------
Level B Level A harassment threshold \1\
harassment -------------------------------------------------------------------------------
threshold
Survey ---------------- Low frequency Mid frequency High Otariid Phocid
All marine cetaceans cetaceans frequency Pinnipeds Pinnipeds
mammals cetaceans
--------------------------------------------------------------------------------------------------------------------------------------------------------
North Island 2-D Survey................................. 1,931.3 144.5 3.9 65.8 3.1 12.0
North Island 3-D Survey................................. 1,067.3 29.1 4.5 47.5 3.9 10.0
South Island 2-D Survey................................. 1,913.4 111.1 4.1 86.3 3.2 12.4
--------------------------------------------------------------------------------------------------------------------------------------------------------
\1\ Level A ensonified areas are estimated based on the greater of the distances calculated to Level A isopleths using dual criteria (SELcum and
peakSPL).
Note: Estimated areas shown for single day do not include additional 50 percent contingency.
Factors including water depth, array configuration, and proportion
of each survey occurring within territorial seas (versus within the
EEZ) were also accounted for in estimates of ensonified areas. This was
accomplished by selecting track lines for a single day (for each of the
three proposed surveys) that were representative of the entire proposed
survey(s) and using those representative track lines to calculate daily
ensonified areas. Daily track line distance was selected depending on
array configuration (i.e., 160 km per day for the proposed 2-D surveys,
200 km per day for the proposed 3-D survey). Representative daily track
lines were chosen to reflect the proportion of water depths (i.e., less
than 100 m, 100-1,000 m, and greater than 1,000 m) expected to occur
for that entire survey (Table 5)
[[Page 45141]]
as distances to isoploths corresponding to harassment vary depending on
water depth (Table 5), and water depths vary considerably within the
planned survey areas (Table 1). Representative track lines were also
selected to reflect the amount of effort in the New Zealand territorial
sea (versus within the New Zealand EEZ), for each of the three surveys,
as NMFS does not authorize the incidental take of marine mammals within
the New Zealand territorial sea. For example, for the proposed North
Island 2-D survey approximately 9 percent of survey effort would occur
in the New Zealand territorial sea (Table 1). Thus, representative
track lines that were chosen also had approximately 9 percent of survey
effort in territorial seas; the resultant ensonified areas within
territorial seas were excluded from take calculations.
Estimated takes for all marine mammal species are shown in Tables
11, 12, 13 and 14. As described above, we propose to authorize the
incidental takes that are expected to occur as a result of the proposed
surveys within the New Zealand EEZ but outside of the New Zealand
territorial sea.
Table 11--Numbers of Potential Incidental Take of Marine Mammals Proposed for Authorization During L-DEO's
Proposed North Island 2-D Seismic Survey off New Zealand
----------------------------------------------------------------------------------------------------------------
Total
Total proposed Level
Density (#/ Proposed Proposed proposed A and Level B
Species 1,000 km\2\) Level A takes Level B takes Level A and takes as a
Level B takes percentage of
population
----------------------------------------------------------------------------------------------------------------
Southern right whale............ 0.24 2 23 25 0.18
Pygmy right whale............... 0.10 1 10 11 N.A.
Humpback whale.................. 0.24 2 23 25 0.05
Bryde's whale................... 0.14 1 14 15 0.03
Common minke whale.............. 0.14 1 14 15 <0.01
Antarctic minke whale........... 0.14 1 14 15 <0.01
Sei whale....................... 0.14 1 14 15 0.13
Fin whale....................... 0.25 2 24 26 0.14
Blue whale...................... 0.04 0 4 4 0.11
Sperm whale..................... 2.89 0 293 293 0.82
Cuvier's beaked whale........... 2.62 0 265 221 0.04
Arnoux's beaked whale........... 2.62 0 265 221 0.04
Southern bottlenose whale....... 1.74 0 177 148 0.02
Shepard's beaked whale.......... 1.74 0 177 148 0.02
Hector's beaked whale........... 1.74 0 177 148 0.02
True's beaked whale............. 0.87 0 89 74 N.A.
Gray's beaked whale............. 3.49 1 353 354 0.05
Andrew's beaked whale........... 1.74 0 177 148 0.02
Strap-toothed whale............. 2.62 0 265 221 0.04
Blainville's beaked whale....... 0.87 0 89 74 0.01
Spade-toothed whale............. 0.87 0 89 74 0.01
Bottlenose dolphin.............. 5.12 1 519 520 N.A.
Short-beaked common dolphin..... 10.25 2 1038 1040 N.A.
Dusky dolphin................... 5.12 1 519 520 3.61
Southern right-whale dolphin.... 3.07 1 312 313 N.A.
Risso's dolphin................. 2.05 0 208 208 N.A.
False killer whale.............. 3.07 1 312 313 N.A.
Killer whale.................... 1.91 0 194 194 0.20
Long-finned pilot whale......... 8.28 1 838 839 0.35
Short-finned pilot whale........ 4.10 1 415 416 N.A.
Pygmy sperm whale............... 1.74 3 172 175 N.A.
Hourglass dolphin............... 4.16 12 410 418 0.12
Hector's dolphin................ 0 0 0 0 0
Spectacled porpoise............. 0 0 0 0 0
New Zealand fur seal............ 22.50 3 2279 2283 0.50
New Zealand sea lion............ 0 0 0 0 0
Southern elephant seal.......... 4.50 2 454 456 0.03
Leopard seal.................... 2.25 1 227 228 0.04
----------------------------------------------------------------------------------------------------------------
Table 12--Numbers of Potential Incidental Take of Marine Mammals Proposed for Authorization During L-DEO's
Proposed North Island 3-D Seismic Survey off New Zealand
----------------------------------------------------------------------------------------------------------------
Total
Total proposed Level
Density (#/ Proposed Proposed proposed A and Level B
Species 1,000 km\2\) Level A takes Level B takes Level A and takes as a
Level B takes percentage of
population
----------------------------------------------------------------------------------------------------------------
Southern right whale............ 0.24 0 13 13 0.09
Pygmy right whale............... 0.10 0 5 5 N.A.
Humpback whale.................. 0.24 0 13 13 0.03
[[Page 45142]]
Bryde's whale................... 0.14 0 8 8 0.01
Common minke whale.............. 0.14 0 8 8 <0.01
Antarctic minke whale........... 0.14 0 8 8 <0.01
Sei whale....................... 0.14 0 8 8 0.07
Fin whale....................... 0.25 0 13 13 0.07
Blue whale...................... 0.04 0 3 3 0.05
Sperm whale..................... 2.89 1 153 154 0.43
Cuvier's beaked whale........... 2.62 0 138 138 0.02
Arnoux's beaked whale........... 2.62 0 138 138 0.02
Southern bottlenose whale....... 1.74 0 92 92 0.01
Shepard's beaked whale.......... 1.74 0 92 92 0.01
Hector's beaked whale........... 1.74 0 92 92 0.01
True's beaked whale............. 0.87 0 46 46 N.A.
Gray's beaked whale............. 3.49 1 184 185 0.03
Andrew's beaked whale........... 1.74 0 92 92 0.01
Strap-toothed whale............. 2.62 0 138 138 0.02
Blainville's beaked whale....... 0.87 0 46 46 0.01
Spade-toothed whale............. 0.87 0 46 46 0.01
Bottlenose dolphin.............. 5.12 1 270 271 N.A.
Short-beaked common dolphin..... 10.25 2 540 540 N.A.
Dusky dolphin................... 5.12 1 270 271 1.88
Southern right-whale dolphin.... 3.07 1 162 163 N.A.
Risso's dolphin................. 2.05 0 108 108 N.A.
False killer whale.............. 3.07 1 162 163 N.A.
Killer whale.................... 1.91 0 101 101 0.11
Long-finned pilot whale......... 8.28 2 436 438 0.18
Short-finned pilot whale........ 4.10 1 216 217 N.A.
Pygmy sperm whale............... 1.74 3 89 92 N.A.
Hourglass dolphin............... 4.16 8 212 220 0.12
Hector's dolphin................ 0 0 0 0 0
Spectacled porpoise............. 0 0 0 0 0
New Zealand fur seal............ 22.50 4 1186 1190 0.50
New Zealand sea lion............ 0 0 0 0 0
Southern elephant seal.......... 4.50 2 236 238 0.03
Leopard seal.................... 2.25 1 118 119 0.04
----------------------------------------------------------------------------------------------------------------
Table 13--Numbers of Potential Incidental Take of Marine Mammals Proposed for Authorization During L-DEO's
Proposed South Island 2-D Seismic Survey off New Zealand
----------------------------------------------------------------------------------------------------------------
Total
Total proposed Level
Density (#/ Proposed Proposed proposed A and Level B
Species 1,000 km\2\) Level A takes Level B takes Level A and takes as a
Level B takes percentage of
population
----------------------------------------------------------------------------------------------------------------
Southern right whale............ 0.24 1 15 16 0.11
Pygmy right whale............... 0.10 0 6 6 N.A.
Humpback whale.................. 0.19 1 12 13 0.02
Bryde's whale................... 0.00 0 0 0 0
Common minke whale.............. 0.14 0 9 9 <0.01
Antarctic minke whale........... 0.14 0 9 9 <0.01
Sei whale....................... 0.14 0 9 9 0.08
Fin whale....................... 0.25 1 15 16 0.09
Blue whale...................... 0.04 0 3 3 0.08
Sperm whale..................... 2.89 0 183 183 0.51
Cuvier's beaked whale........... 2.62 0 165 165 0.02
Arnoux's beaked whale........... 2.62 0 165 165 0.02
Southern bottlenose whale....... 1.74 0 110 110 0.02
Shepard's beaked whale.......... 1.74 0 110 110 0.02
Hector's beaked whale........... 1.74 0 110 110 0.02
True's beaked whale............. 0.87 0 55 55 N.A.
Gray's beaked whale............. 3.49 0 220 220 0.03
Andrew's beaked whale........... 1.74 0 110 110 0.02
[[Page 45143]]
Strap-toothed whale............. 2.62 0 165 165 0.02
Blainville's beaked whale....... 0.87 0 55 55 0.01
Spade-toothed whale............. 0.87 0 55 55 0.01
Bottlenose dolphin.............. 4.78 1 302 303 N.A.
Short-beaked common dolphin..... 4.78 1 302 303 N.A.
Dusky dolphin................... 7.65 1 483 484 3.36
Southern right-whale dolphin.... 2.87 0 181 181 N.A.
Risso's dolphin................. 1.91 0 121 121 N.A.
False killer whale.............. 2.87 0 181 181 N.A.
Killer whale.................... 1.91 0 121 121 0.13
Long-finned pilot whale......... 8.28 1 522 523 0.22
Short-finned pilot whale........ 1.91 0 121 121 N.A.
Pygmy sperm whale............... 1.74 4 106 110 N.A.
Hourglass dolphin............... 4.16 10 253 263 0.15
Hector's dolphin................ 0.04 0 3 3 0.01
Spectacled porpoise............. 1.91 5 117 122 N.A.
New Zealand fur seal............ 22.50 2 1419 1421 0.59
New Zealand sea lion............ 9.00 1 568 569 4.80
Southern elephant seal.......... 4.50 2 283 285 0.04
Leopard seal.................... 2.25 1 142 143 0.05
----------------------------------------------------------------------------------------------------------------
Table 14--Total Numbers of Potential Incidental Take of Marine Mammals Proposed for Authorization During L-DEO's
Proposed North Island 3-D Survey, North Island 2-D Survey, and South Island 3-D Surveys of the R/V Langseth off
New Zealand
----------------------------------------------------------------------------------------------------------------
Total
Total proposed Level
Density (#/ Proposed Proposed proposed A and Level B
Species 1,000 km\2\) Level A takes Level B takes Level A and takes as a
Level B takes percentage of
population
----------------------------------------------------------------------------------------------------------------
Southern right whale............ 0.24 3 51 54 0.38
Pygmy right whale............... 0.10 1 21 22 N.A.
Humpback whale.................. 0.19 3 48 51 0.1
Bryde's whale................... 0.00 1 22 23 0.04
Common minke whale.............. 0.14 1 31 32 N.A.
Antarctic minke whale........... 0.14 1 31 32 N.A.
Sei whale....................... 0.14 1 31 32 0.28
Fin whale....................... 0.25 3 52 55 0.3
Blue whale...................... 0.04 0 10 10 0.24
Sperm whale..................... 2.89 1 629 630 1.76
Cuvier's beaked whale........... 2.62 0 568 568 0.08
Arnoux's beaked whale........... 2.62 0 568 568 0.08
Southern bottlenose whale....... 1.74 0 379 379 0.05
Shepard's beaked whale.......... 1.74 0 379 379 0.05
Hector's beaked whale........... 1.74 0 379 379 0.05
True's beaked whale............. 0.87 0 190 190 N.A.
Gray's beaked whale............. 3.49 2 757 759 0.11
Andrew's beaked whale........... 1.74 0 379 379 0.05
Strap-toothed whale............. 2.62 0 568 568 0.08
Blainville's beaked whale....... 0.87 0 190 190 0.03
Spade-toothed whale............. 0.87 0 190 190 0.03
Bottlenose dolphin.............. 4.78 3 1091 1094 N.A.
Short-beaked common dolphin..... 4.78 5 1880 1885 N.A.
Dusky dolphin................... 7.65 3 1272 1275 8.85
Southern right-whale dolphin.... 2.87 2 655 657 N.A.
Risso's dolphin................. 1.91 0 437 437 N.A.
False killer whale.............. 2.87 2 655 657 N.A.
Killer whale.................... 1.91 0 416 416 0.44
Long-finned pilot whale......... 8.28 4 1796 1800 0.75
Short-finned pilot whale........ 1.91 2 752 754 N.A.
Pygmy sperm whale............... 1.74 12 367 379 N.A.
Hourglass dolphin............... 4.16 30 875 905 0.39
[[Page 45144]]
Hector's dolphin................ 0.04 0 3 3 0.01
Spectacled porpoise............. 1.91 5 117 122 N.A.
New Zealand fur seal............ 22.50 9 4884 4893 1.59
New Zealand sea lion............ 9.00 1 568 569 0.38
Southern elephant seal.......... 4.50 6 973 979 N.A.
Leopard seal.................... 2.25 3 487 490 0.1
----------------------------------------------------------------------------------------------------------------
It should be noted that the proposed take numbers shown in Tables
11, 12, 13 and 14 are expected to be conservative for several reasons.
First, in the calculations of estimated take, 50 percent has been added
in the form of operational survey days (equivalent to adding 50 percent
to the proposed line km to be surveyed) to account for the possibility
of additional seismic operations associated with airgun testing and
repeat coverage of any areas where initial data quality is sub-
standard, and in recognition of the uncertainties in the density
estimates used to estimate take as described above. Additionally,
marine mammals would be expected to move away from a loud sound source
that represents an aversive stimulus, such as an airgun array,
potentially reducing the number of Level A takes. However, the extent
to which marine mammals would move away from the sound source is
difficult to quantify and is therefore not accounted for in the take
estimates shown in 11, 12, 13 and 14.
For some marine mammal species, we propose to authorize a different
number of incidental takes than the number of incidental takes
requested by L-DEO (see Tables 18, 19 and 20 in the IHA application for
requested take numbers). For instance, for several species, L-DEO
increased the take request from the calculated take number to 1 percent
of the estimated population size. We do not believe it is likely that 1
percent of the estimated population size of those species will be taken
by L-DEO's proposed survey, therefore we do not propose to authorize
the take numbers requested by L-DEO in their IHA application (LGL,
2017). However, in recognition of the uncertainties in the density
estimates used to estimate take as described above, we believe it is
reasonable to assume that actual takes may exceed numbers of takes
calculated based on available density estimates; therefore, we have
increased take estimates for all marine mammal species by an additional
25 percent, to account for the fact that density estimates used to
estimate take may be underestimates of actual densities of marine
mammals in the survey area. Additionally, L-DEO requested authorization
for 10 takes of Hector's dolphins during the North Island 2-D survey
(LGL, 2017). However, we do not propose to authorize any takes of
Hector's dolphins during North Island surveys. We believe the
likelihood of the proposed North Island 2-D survey encountering a
Hector's dolphin is extremely low. As described above, the North Island
subpopulation of Hector's dolphin (aka Maui dolphin) is very unlikely
to be encountered during either proposed North Island survey due to the
very low estimated abundance of the subpopulation and due to the
geographic isolation of the subpopulation (currently limited to the
west coast of the North Island). Additionally, while it would be
extremely unlikely for the proposed surveys to encounter a Hector's
dolphin during North Island surveys, any Hector's dolphin encountered
in waters off the North Island would possibly be a member of the Maui
dolphin subspecies. As described above, the Maui dolphin is facing a
high risk of extinction (Manning and Grantz, 2016) and has a population
size estimated at just 55-63 individuals (Hamner et al. 2014; Baker et
al. 2016). Therefore, we seek to avoid the remote possibility of
exposure of Maui dolphins to airgun sounds. As such, we do not propose
to authorize any takes of Hector's dolphins during L-DEO's proposed
North Island surveys. Additionally, we propose a mitigation measure
that would require shutdown of the airgun array upon observation of a
Hector's dolphin at any distance during both proposed North Island
surveys (described below in Proposed Mitigation), which further
minimizes the potential for any take of Hector's dolphins during the
proposed North Island surveys.
Proposed Mitigation
In order to issue an IHA under Section 101(a)(5)(D) of the MMPA,
NMFS must set forth the permissible methods of taking pursuant to such
activity, ``and other means of effecting the least practicable 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 (latter not applicable for this action). NMFS
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, as well as subsistence uses where applicable, we
carefully consider two primary factors:
(1) the manner in which, and the degree to which, the successful
implementation of the measure(s) is expected to reduce impacts to
marine mammals, marine mammal species or stocks, and their habitat.
This considers the nature of the potential adverse impact being
mitigated (likelihood, scope, range). It further considers the
likelihood that the measure will be effective if implemented
(probability of accomplishing the mitigating result if implemented as
planned) the likelihood
[[Page 45145]]
of effective implementation (probability implemented as planned), and
(2) the practicability of the measures for applicant
implementation, which may consider such things as cost, impact on
operations, and, in the case of a military readiness activity,
personnel safety, practicality of implementation, and impact on the
effectiveness of the military readiness activity.
L-DEO has reviewed mitigation measures employed during seismic
research surveys authorized by NMFS under previous incidental
harassment authorizations, as well as recommended best practices in
Richardson et al. (1995), Pierson et al. (1998), Weir and Dolman
(2007), Nowacek et al. (2013), Wright (2014), and Wright and Cosentino
(2015), and has incorporated a suite of proposed mitigation measures
into their project description based on the above sources.
To reduce the potential for disturbance from acoustic stimuli
associated with the activities, L-DEO has proposed to implement the
following mitigation measures for marine mammals:
(1) Vessel-based visual mitigation monitoring;
(2) Vessel-based passive acoustic monitoring;
(3) Establishment of an exclusion zone;
(4) Power down procedures;
(5) Shutdown procedures;
(6) Ramp-up procedures; and
(7) Vessel strike avoidance measures.
In addition to the mitigation measures proposed by L-DEO, NMFS has
proposed the following additional measure: Shutdown of the acoustic
source is required upon observation of a beaked whale or kogia spp., a
large whale with calf, or a Hector's dolphin (during North Island
surveys only) at any distance.
Vessel-Based Visual Mitigation Monitoring
Protected Species Observer (PSO) observations would take place
during all daytime airgun operations and nighttime start ups (if
applicable) of the airguns. Airgun operations would be suspended when
marine mammals are observed within, or about to enter, designated
Exclusion Zones (as described below). PSOs would also watch for marine
mammals near the vessel for at least 30 minutes prior to the planned
start of airgun operations. PSOs would monitor the entire extent of the
modeled Level B harassment zone (Table 4) (or, as far as they are able
to see, if they cannot see to the extent of the estimated Level B
harassment zone). Observations would also be made during daytime
periods when the Langseth is underway without seismic operations, such
as during transits, to allow for comparison of sighting rates and
behavior with and without airgun operations and between acquisition
periods.
During seismic operations, a minimum of four visual PSOs would be
based aboard the Langseth. PSOs would be appointed by L-DEO, with NMFS'
approval. During the majority of seismic operations, two PSOs would
monitor for marine mammals around the seismic vessel. Use of two
simultaneous observers would increase the effectiveness of detecting
marine mammals around the source vessel. However, during meal times,
only one PSO may be on duty. PSO(s) would be on duty in shifts of
duration no longer than 4 hours. Other crew would also be instructed to
assist in detecting marine mammals and in implementing mitigation
requirements (if practical). Before the start of the seismic survey,
the crew would be given additional instruction in detecting marine
mammals and implementing mitigation requirements. The Langseth is a
suitable platform for marine mammal observations. When stationed on the
observation platform, PSOs would have a good view around the entire
vessel. During daytime, the PSO(s) would scan the area around the
vessel systematically with reticle binoculars (e.g., 7x50 Fujinon),
Big-eye binoculars (25x150), and with the naked eye.
The PSOs must have no tasks other than to conduct observational
effort, record observational data, and communicate with and instruct
relevant vessel crew with regard to the presence of marine mammals and
mitigation requirements. PSO resumes would be provided to NMFS for
approval. At least two PSOs must have a minimum of 90 days at-sea
experience working as PSOs during a high energy seismic survey, with no
more than eighteen months elapsed since the conclusion of the at-sea
experience. One ``experienced'' visual PSO would be designated as the
lead for the entire protected species observation team. The lead would
coordinate duty schedules and roles for the PSO team and serve as
primary point of contact for the vessel operator. The lead PSO would
devise the duty schedule such that ``experienced'' PSOs are on duty
with those PSOs with appropriate training but who have not yet gained
relevant experience, to the maximum extent practicable.
The PSOs must have successfully completed relevant training,
including completion of all required coursework and passing a written
and/or oral examination developed for the training program, and must
have successfully attained a bachelor's degree from an accredited
college or university with a major in one of the natural sciences and a
minimum of 30 semester hours or equivalent in the biological sciences
and at least one undergraduate course in math or statistics. The
educational requirements may be waived if the PSO has acquired the
relevant skills through alternate training, including (1) secondary
education and/or experience comparable to PSO duties; (2) previous work
experience conducting academic, commercial, or government-sponsored
marine mammal surveys; or (3) previous work experience as a PSO. The
PSO should demonstrate good standing and consistently good performance
of PSO duties.
In summary, a typical daytime cruise would have scheduled two
observers (visual) on duty from the observation platform, and an
acoustic observer on the passive acoustic monitoring system.
Vessel-Based Passive Acoustic Mitigation Monitoring
Passive acoustic monitoring (PAM) would take place to complement
the visual monitoring program. Visual monitoring typically is not
effective during periods of poor visibility or at night, and even with
good visibility, is unable to detect marine mammals when they are below
the surface or beyond visual range. Acoustic monitoring can be used in
addition to visual observations to improve detection, identification,
and localization of cetaceans. The acoustic monitoring would serve to
alert visual observers (if on duty) when vocalizing cetaceans are
detected. It is only useful when marine mammals vocalize, but it can be
effective either by day or by night and does not depend on good
visibility. It would be monitored in real time so that visual observers
can be alerted when marine mammals are detected acoustically.
The PAM system consists of hardware (i.e., hydrophones) and
software. The ``wet end'' of the system consists of a towed hydrophone
array that is connected to the vessel by a tow cable. A deck cable
would connect the tow cable to the electronics unit on board where the
acoustic station, signal conditioning, and processing system would be
located. The acoustic signals received by the hydrophones are
amplified, digitized, and then processed by the software.
At least one acoustic PSO (in addition to the four visual PSOs)
would be on board. The towed hydrophones would
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be monitored 24 hours per day (either by the acoustic PSO or by a
visual PSO trained in the PAM system if the acoustic PSO is on break)
while at the seismic survey area during airgun operations, and during
most periods when the Langseth is underway while the airguns are not
operating. However, PAM may not be possible if damage occurs to the
array or back-up systems during operations. One PSO would monitor the
acoustic detection system at any one time, in shifts no longer than six
hours, by listening to the signals via headphones and/or speakers and
watching the real-time spectrographic display for frequency ranges
produced by cetaceans.
When a vocalization is detected, while visual observations are in
progress, the acoustic PSO would contact the visual PSOs immediately,
to alert them to the presence of marine mammals (if they have not
already been detected visually), in order to facilitate a power down or
shut down, if required. The information regarding the marine mammal
acoustic detection would be entered into a database.
Exclusion Zone and Buffer Zone
An exclusion zone (EZ) is a defined area within which occurrence of
a marine mammal triggers mitigation action intended to reduce the
potential for certain outcomes, e.g., auditory injury, disruption of
critical behaviors. The PSOs would establish a minimum EZ with a 500 m
radius for the 36 airgun array and the 18 airgun array. The 500 m EZ
would be based on radial distance from any element of the airgun array
(rather than being based on the center of the array or around the
vessel itself). With certain exceptions (described below), if a marine
mammal appears within, enters, or appears on a course to enter this
zone, the acoustic source would be powered down (see Power Down
Procedures below). In addition to the 500 m EZ for the full arrays, a
100 m exclusion zone would be established for the single 40 in \3\
airgun. With certain exceptions (described below), if a marine mammal
appears within, enters, or appears on a course to enter this zone the
acoustic source would be shut down entirely (see Shutdown Procedures
below). Additionally, power down of the full arrays would last no more
than 30 minutes maximum at any given time; thus the arrays would be
shut down entirely if, after 30 minutes of the array being powered
down, a marine mammal remains inside the 500 m EZ.
In their IHA application, L-DEO proposed to establish EZs based
upon modeled radial distances to auditory injury zones (e.g., power
down would occur when a marine mammal entered or appeared likely to
enter the zone(s) within which auditory injury is expected to occur
based on modeling) (Tables 7, 8, 9). However, we instead propose the
500 m EZ as described above. The 500 m EZ is intended to be
precautionary in the sense that it would be expected to contain sound
exceeding peak pressure injury criteria for all cetacean hearing
groups, while also providing a consistent, reasonably observable zone
within which PSOs would typically be able to conduct effective
observational effort. Additionally, a 500-m EZ is expected to minimize
the likelihood that marine mammals will be exposed to levels likely to
result in more severe behavioral responses. Although significantly
greater distances may be observed from an elevated platform under good
conditions, we believe that 500 m is likely regularly attainable for
PSOs using the naked eye during typical conditions.
An appropriate EZ based on cumulative sound exposure level
(SELcum) criteria would be dependent on the animal's applied
hearing range and how that overlaps with the frequencies produced by
the sound source of interest (i.e., via marine mammal auditory
weighting functions) (NMFS, 2016), and may be larger in some cases than
the zones calculated on the basis of the peak pressure thresholds (and
larger than 500 m) depending on the species in question and the
characteristics of the specific airgun array. In particular, the EZ
radii would be larger for low-frequency cetaceans, because their most
susceptible hearing range overlaps the low frequencies produced by
airguns, but the zones would remain very small for mid-frequency
cetaceans (i.e., including the ``small delphinoids'' described below),
whose range of best hearing largely does not overlap with frequencies
produced by airguns.
Use of monitoring and shutdown or power-down measures within
defined exclusion zone distances is inherently an essentially
instantaneous proposition--a rule or set of rules that requires
mitigation action upon detection of an animal. This indicates that
definition of an exclusion zone on the basis of cumulative sound
exposure level thresholds, which require that an animal accumulate some
level of sound energy exposure over some period of time (e.g., 24
hours), has questionable relevance as a standard protocol. A PSO aboard
a mobile source will typically have no ability to monitor an animal's
position relative to the acoustic source over relevant time periods for
purposes of understanding whether auditory injury is likely to occur on
the basis of cumulative sound exposure and, therefore, whether action
should be taken to avoid such potential.
Cumulative SEL thresholds are more relevant for purposes of
modeling the potential for auditory injury than they are for dictating
real-time mitigation, though they can be informative (especially in a
relative sense). We recognize the importance of the accumulation of
sound energy to an understanding of the potential for auditory injury
and that it is likely that, at least for low-frequency cetaceans, some
potential auditory injury is likely impossible to mitigate and should
be considered for authorization.
In summary, our intent in prescribing a standard exclusion zone
distance is to (1) encompass zones for most species within which
auditory injury could occur on the basis of instantaneous exposure; (2)
provide additional protection from the potential for more severe
behavioral reactions (e.g., panic, antipredator response) for marine
mammals at relatively close range to the acoustic source; (3) provide
consistency for PSOs, who need to monitor and implement the exclusion
zone; and (4) to define a distance within which detection probabilities
are reasonably high for most species under typical conditions.
Our use of 500 m as the EZ is a reasonable combination of factors.
This zone is expected to contain all potential auditory injury for all
marine mammals (high-frequency, mid-frequency and low-frequency
cetacean functional hearing groups and otariid and phocid pinnipeds) as
assessed against peak pressure thresholds (NMFS, 2016) (Tables 7, 8,
9). It is also expected to contain all potential auditory injury for
high-frequency and mid-frequency cetaceans as well as otariid and
phocid pinnipeds as assessed against SELcum thresholds
(NMFS, 2016) (Tables 7, 8, 9). It has proven to be practicable through
past implementation in seismic surveys conducted for the oil and gas
industry in the Gulf of Mexico (as regulated by BOEM pursuant to the
Outer Continental Shelf Lands Act (OCSLA) (43 U.S.C. 1331-1356)). In
summary, a practicable criterion such as the proposed EZs has the
advantage of simplicity while still providing in most cases a zone
larger than relevant auditory injury zones, given realistic movement of
source and receiver.
The PSOs would also establish and monitor a 1,000 m buffer zone.
During operation of the airgun arrays, occurrence of marine mammals
within the 1,000 m buffer zone (but outside the
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500 m EZ) would be communicated to the vessel operator to prepare for
potential power down or shutdown of the acoustic source. The buffer
zone is discussed further under Ramp Up Procedures below. PSOs would
also monitor the entire extent of the estimated Level B harassment zone
(Table 4) (or, as far as they are able to see, if they cannot see to
the extent of the estimated Level B harassment zone).
Power Down Procedures
A power down involves decreasing the number of airguns in use such
that the radius of the mitigation zone is decreased to the extent that
marine mammals are no longer in, or about to enter, the 500 m EZ.
During a power down, one 40-in\3\ airgun would be operated. The
continued operation of one 40-in\3\ airgun is intended to alert marine
mammals to the presence of the seismic vessel in the area, and to allow
them to leave the area of the seismic vessel if they choose. In
contrast, a shutdown occurs when all airgun activity is suspended
(shutdown procedures are discussed below). If a marine mammal is
detected outside the 500 m EZ but appears likely to enter the 500 m EZ,
the airguns would be powered down before the animal is within the 500 m
EZ. Likewise, if a mammal is already within the 500 m EZ when first
detected, the airguns would be powered down immediately. During a power
down of the airgun array, the 40-in\3\ airgun would be operated.
Following a power down, airgun activity would not resume until the
marine mammal has cleared the 500 m EZ. The animal would be considered
to have cleared the 500 m EZ if the following conditions have been met:
[ballot] It is visually observed to have departed the 500 m EZ, or
[ballot] it has not been seen within the 500 m EZ for 15 min in the
case of small odontocetes and pinnipeds, or
[ballot] it has not been seen within the 500 m EZ for 30 min in the
case of mysticetes and large odontocetes, including sperm, pygmy sperm,
dwarf sperm, and beaked whales.
This power down requirement would be in place for all marine
mammals, with the exception of small delphinoids under certain
circumstances. As defined here, the small delphinoid group is intended
to encompass those members of the Family Delphinidae most likely to
voluntarily approach the source vessel for purposes of interacting with
the vessel and/or airgun array (e.g., bow riding). This exception to
the power down requirement would apply solely to specific genera of
small dolphins --Tursiops, Delphinus and Lissodelphis -- and would only
apply if the animals were traveling, including approaching the vessel.
If, for example, an animal or group of animals is stationary for some
reason (e.g., feeding) and the source vessel approaches the animals,
the power down requirement applies. An animal with sufficient incentive
to remain in an area rather than avoid an otherwise aversive stimulus
could either incur auditory injury or disruption of important behavior.
If there is uncertainty regarding identification (i.e., whether the
observed animal(s) belongs to the group described above) or whether the
animals are traveling, the power down or shutdown would be implemented.
Note that small dolphins in the genera Lagenorhynchus and
Cephalorhynchus are not included in the proposed power down/shutdown
exception.
We include this small delphinoid exception because power-down/
shutdown requirements for small delphinoids under all circumstances
represent practicability concerns without likely commensurate benefits
for the animals in question. Small delphinoids are generally the most
commonly observed marine mammals in the specific geographic region and
would typically be the only marine mammals likely to intentionally
approach the vessel. As described below, auditory injury is extremely
unlikely to occur for mid-frequency cetaceans (e.g., delphinids), as
this group is relatively insensitive to sound produced at the
predominant frequencies in an airgun pulse while also having a
relatively high threshold for the onset of auditory injury (i.e.,
permanent threshold shift). Please see Potential Effects of the
Specified Activity on Marine Mammals above for further discussion of
sound metrics and thresholds and marine mammal hearing.
A large body of anecdotal evidence indicates that small delphinoids
commonly approach vessels and/or towed arrays during active sound
production for purposes of bow riding, with no apparent effect observed
in those delphinoids (e.g., Barkaszi et al., 2012). The potential for
increased shutdowns resulting from such a measure would require the
Langseth to revisit the missed track line to reacquire data, resulting
in an overall increase in the total sound energy input to the marine
environment and an increase in the total duration over which the survey
is active in a given area. Although other mid-frequency hearing
specialists (e.g., large delphinoids) are no more likely to incur
auditory injury than are small delphinoids, they are much less likely
to approach vessels. Therefore, retaining a power-down/shutdown
requirement for large delphinoids would not have similar impacts in
terms of either practicability for the applicant or corollary increase
in sound energy output and time on the water. We do anticipate some
benefit for a power-down/shutdown requirement for large delphinoids in
that it simplifies somewhat the total range of decision-making for PSOs
and may preclude any potential for physiological effects other than to
the auditory system as well as some more severe behavioral reactions
for any such animals in close proximity to the source vessel.
A power down could occur for no more than 30 minutes maximum at any
given time. If, after 30 minutes of the array being powered down,
marine mammals had not cleared the 500 m EZ (as described above), a
shutdown of the array would be implemented (see Shut Down Procedures,
below). Power down is only allowed in response to the presence of
marine mammals within the designated EZ. Thus, the single 40 in\3\
airgun, which would be operated during power downs, may not be operated
continuously throughout the night or during transits from one line to
another.
Shut Down Procedures
The single 40-in\3\ operating airgun would be shut down if a marine
mammal is seen within or approaching the 100 m EZ for the single 40-
in\3\ airgun. Shutdown would be implemented if (1) an animal enters the
100 m EZ of the single 40-in\3\ airgun after a power down has been
initiated, or (2) an animal is initially seen within the 100 m EZ of
the single 40-in\3\ airgun when more than one airgun (typically the
full array) is operating. Airgun activity would not resume until the
marine mammal has cleared the 500 m EZ. Criteria for judging that the
animal has cleared the EZ would be as described above. A shutdown of
the array would be implemented if, after 30 minutes of the array being
powered down, marine mammals have not cleared the 500 m EZ (as
described above).
The shutdown requirement, like the power down requirement, would be
waived for dolphins of the following genera: Tursiops, Delphinus and
Lissodelphis. The shutdown waiver only applies if the animals are
traveling, including approaching the vessel. If animals are stationary
and the source vessel approaches the animals, the shutdown requirement
would apply. If there is uncertainty regarding identification (i.e.,
whether the observed animal(s) belongs to the group described above) or
whether the animals are
[[Page 45148]]
traveling, the shutdown would be implemented.
In addition to the measures proposed by L-DEO, NMFS also proposes
that a shutdown of the acoustic source would also be required, at any
distance, upon observation of the following: A large whale (i.e., sperm
whale or any baleen whale) with a calf; a beaked whale or kogia spp.;
or, a Hector's dolphin (during North Island surveys only). These are
the only three potential scenarios that would require shutdown of the
array for marine mammals observed beyond the 100 m EZ for the single 40
in\3\ airgun. The shutdown requirement for Hector's dolphin during
North Island surveys is designed to avoid any potential for exposure of
a Maui dolphin to seismic airgun sounds. Maui dolphins are not expected
to occur in the proposed survey areas off the North Island based on
their current range. However, as described above, there have been
occasional sightings and strandings of Hector's dolphins off the east
coast of the North Island. While the likelihood of L-DEO's proposed
surveys encountering a Maui dolphin is considered extremely low, we
nonetheless include this measure to avoid any potential for exposure of
a Maui dolphin to airgun sounds. In the event of a shutdown due to
observation of a shutdown due to observation of a beaked whale, kogia
app., or large whale with calf, ramp-up procedures would not be
initiated until the Hector's dolphin has not been seen at any distance
for 30 minutes. In the event of a shutdown due to observation of a
Hector's dolphin (during North Island surveys only), ramp-up procedures
would not be initiated until the Hector's dolphin has not been seen at
any distance for 15 minutes.
Ramp-Up Procedures
Ramp-up of an acoustic source is intended to provide a gradual
increase in sound levels following a power down or shutdown, enabling
animals to move away from the source if the signal is sufficiently
aversive prior to its reaching full intensity. The ramp-up procedure
involves a step-wise increase in the number of airguns firing and total
array volume until all operational airguns are activated and the full
volume is achieved. Ramp-up would be required after the array is
powered down or shut down due to mitigation. If the airgun array has
been shut down for reasons other than mitigation (e.g., mechanical
difficulty) for a period of less than 30 minutes, it may be activated
again without ramp-up if PSOs have maintained constant visual and
acoustic observation and no visual detections of any marine mammal have
occurred within the buffer zone and no acoustic detections have
occurred. This is the only scenario under which ramp up would not be
required.
Ramp-up would begin by activating a single airgun of the smallest
volume in the array and would continue in stages by doubling the number
of active elements at the commencement of each stage, with each stage
of approximately the same duration.
If airguns have been powered down or shut down due to PSO detection
of a marine mammal within or approaching the 500 m EZ, ramp-up would
not be initiated until all marine mammals have cleared the EZ, during
the day or night. Visual and acoustic PSOs are required to monitor
during ramp-up. If a marine mammal were detected by visual PSOs within
or approaching the 500 m EZ during ramp-up, a power down (or shut down
if appropriate) would be implemented as though the full array were
operational. Criteria for clearing the EZ would be as described above.
Thirty minutes of pre-clearance observation are required prior to
ramp-up for any power down or shutdown of longer than 30 minutes (i.e.,
if the array were shut down during transit from one line to another).
This 30 minute pre-clearance period may occur during any vessel
activity (i.e., transit). If a marine mammal is observed within or
approaching the 500 m EZ during this pre-clearance period, ramp-up
would not be initiated until all marine mammals have cleared the EZ.
Criteria for clearing the EZ would be as described above.
Ramp-up would be planned to occur during periods of good visibility
when possible. However, ramp-up would be allowed at night and during
poor visibility if the 500 m EZ and 1,000 m buffer zone have been
monitored by visual PSOs for 30 minutes prior to ramp-up and if
acoustic monitoring has occurred for 30 minutes prior to ramp-up with
no acoustic detections during that period.
The operator would be required to notify a designated PSO of the
planned start of ramp-up as agreed-upon with the lead PSO. A designated
PSO must be notified again immediately prior to initiating ramp-up
procedures and the operator must receive confirmation from the PSO to
proceed. The operator must provide information to PSOs documenting that
appropriate procedures were followed. Following deactivation of the
array for reasons other than mitigation, the operator would be required
to communicate the near-term operational plan to the lead PSO with
justification for any planned nighttime ramp-up.
L-DEO proposed that ramp up would not occur following an extended
power down (LGL 2017). However, as we do not propose to allow extended
power downs during the proposed survey, we also do not include this as
a proposed mitigation measure and instead propose that ramp up is
required after any power down or shutdown of the array, with the one
exception as described above. L-DEO also proposed that ramp up would
occur when the airgun array begins operating after 8 minutes without
airgun operations (LGL 2017). However, we instead propose the criteria
for ramp up as described above.
Vessel Strike Avoidance
Vessel strike avoidance measures are intended to minimize the
potential for collisions with marine mammals. We note that these
requirements do not apply in any case where compliance would create an
imminent and serious threat to a person or vessel or to the extent that
a vessel is restricted in its ability to maneuver and, because of the
restriction, cannot comply.
The proposed measures include the following: Vessel operator and
crew would maintain a vigilant watch for all marine mammals and slow
down or stop the vessel or alter course to avoid striking any marine
mammal. A visual observer aboard the vessel would monitor a vessel
strike avoidance zone around the vessel according to the parameters
stated below. Visual observers monitoring the vessel strike avoidance
zone would be either third-party observers or crew members, but crew
members responsible for these duties would be provided sufficient
training to distinguish marine mammals from other phenomena. Vessel
strike avoidance measures would be followed during surveys and while in
transit.
The vessel would maintain a minimum separation distance of 100 m
from large whales (i.e., baleen whales and sperm whales). If a large
whale is within 100 m of the vessel the vessel would reduce speed and
shift the engine to neutral, and would not engage the engines until the
whale has moved outside of the vessel's path and the minimum separation
distance has been established. If the vessel is stationary, the vessel
would not engage engines until the whale(s) has moved out of the
vessel's path and beyond 100 m. The vessel would maintain a minimum
separation distance of 50 m from all other marine mammals (with the
exception of delphinids of the genera Tursiops, Delphinus and
Lissodelphis that approach the vessel, as described
[[Page 45149]]
above). If an animal is encountered during transit, the vessel would
attempt to remain parallel to the animal's course, avoiding excessive
speed or abrupt changes in course. Vessel speeds would be reduced to 10
knots or less when mother/calf pairs, pods, or large assemblages of
cetaceans are observed near the vessel.
Based on our evaluation of the applicant's proposed measures, NMFS
has determined that the mitigation measures provide the means effecting
the least practicable impact on the affected species or stocks and
their habitat, paying particular attention to rookeries, mating
grounds, and areas of similar significance.
Proposed Monitoring and Reporting
In order to issue an IHA for an activity, Section 101(a)(5)(D) of
the MMPA states that NMFS must set forth requirements pertaining to the
monitoring and reporting of such taking. The MMPA implementing
regulations at 50 CFR 216.104(a)(13) indicate that requests for
authorizations must include the suggested means of accomplishing the
necessary monitoring and reporting that will result in increased
knowledge of the species and of the level of taking or impacts on
populations of marine mammals that are expected to be present in the
action area. Effective reporting is critical both to compliance as well
as ensuring that the most value is obtained from the required
monitoring.
Monitoring and reporting requirements prescribed by NMFS should
contribute to improved understanding of one or more of the following:
[ballot] Occurrence of marine mammal species or stocks in the area
in which take is anticipated (e.g., presence, abundance, distribution,
density).
[ballot] 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).
[ballot] Individual marine mammal responses (behavioral or
physiological) to acoustic stressors (acute, chronic, or cumulative),
other stressors, or cumulative impacts from multiple stressors.
[ballot] How anticipated responses to stressors impact either: (1)
Long-term fitness and survival of individual marine mammals; or (2)
populations, species, or stocks.
[ballot] Effects on marine mammal habitat (e.g., marine mammal prey
species, acoustic habitat, or other important physical components of
marine mammal habitat).
[ballot] Mitigation and monitoring effectiveness.
L-DEO submitted a marine mammal monitoring and reporting plan in
section XIII of their IHA application. Monitoring that is designed
specifically to facilitate mitigation measures, such as monitoring of
the EZ to inform potential power downs or shutdowns of the airgun
array, are described above and are not repeated here.
L-DEO's monitoring and reporting plan includes the following
measures:
Vessel-Based Visual Monitoring
As described above, PSO observations would take place during
daytime airgun operations and nighttime start ups (if applicable) of
the airguns. During seismic operations, at least four visual PSOs would
be based aboard the Langseth. PSOs would be appointed by L-DEO with
NMFS approval. During the majority of seismic operations, two PSOs
would monitor for marine mammals around the seismic vessel. Use of two
simultaneous observers would increase the effectiveness of detecting
animals around the source vessel. However, during meal times, only one
PSO may be on duty. PSOs would be on duty in shifts of duration no
longer than 4 hours. Other crew would also be instructed to assist in
detecting marine mammals and in implementing mitigation requirements
(if practical). During daytime, PSOs would scan the area around the
vessel systematically with reticle binoculars (e.g., 7x50 Fujinon),
Big-eye binoculars (25x150), and with the naked eye.
PSOs would record data to estimate the numbers of marine mammals
exposed to various received sound levels and to document apparent
disturbance reactions or lack thereof. Data would be used to estimate
numbers of animals potentially `taken' by harassment (as defined in the
MMPA). They would also provide information needed to order a power down
or shutdown of airguns when a marine mammal is within or near the EZ.
When a sighting is made, the following information about the
sighting would be recorded:
1. Species, group size, age/size/sex categories (if determinable),
behavior when first sighted and after initial sighting, heading (if
consistent), bearing and distance from seismic vessel, sighting cue,
apparent reaction to the airguns or vessel (e.g., none, avoidance,
approach, paralleling, etc.), and behavioral pace.
2. Time, location, heading, speed, activity of the vessel, sea
state, visibility, and sun glare.
All observations and power downs or shutdowns would be recorded in
a standardized format. Data would be entered into an electronic
database. The accuracy of the data entry would be verified by
computerized data validity checks as the data are entered and by
subsequent manual checking of the database. These procedures would
allow initial summaries of data to be prepared during and shortly after
the field program and would facilitate transfer of the data to
statistical, graphical, and other programs for further processing and
archiving. The time, location, heading, speed, activity of the vessel,
sea state, visibility, and sun glare would also be recorded at the
start and end of each observation watch, and during a watch whenever
there is a change in one or more of the variables.
Results from the vessel-based observations will provide:
1. The basis for real-time mitigation (airgun power down or shut
down).
2. Information needed to estimate the number of marine mammals
potentially taken by harassment, which must be reported to NMFS.
3. Data on the occurrence, distribution, and activities of marine
mammals in the area where the seismic study is conducted.
4. Information to compare the distance and distribution of marine
mammals relative to the source vessel at times with and without seismic
activity.
5. Data on the behavior and movement patterns of marine mammals
seen at times with and without seismic activity.
Vessel-Based Passive Acoustic Monitoring
PAM would take place to complement the visual monitoring program as
described above. Please see the Mitigation section above for a
description of the PAM system and the acoustic PSO's duties. The
acoustic PSO would record data collected via the PAM system, including
the following: An acoustic encounter identification number, whether it
was linked with a visual sighting, date, time when first and last heard
and whenever any additional information was recorded, position and
water depth when first detected, bearing if determinable, species or
species group (e.g., unidentified dolphin, sperm whale), types and
nature of sounds heard (e.g.,
[[Page 45150]]
clicks, continuous, sporadic, whistles, creaks, burst pulses, strength
of signal, etc.), and any other notable information. Acoustic
detections would also be recorded for further analysis.
Reporting
A report would be submitted to NMFS within 90 days after the end of
the cruise. The report would describe the operations that were
conducted and sightings of marine mammals near the operations. The
report would provide full documentation of methods, results, and
interpretation pertaining to all monitoring. The 90-day report would
summarize the dates and locations of seismic operations, and all marine
mammal sightings (dates, times, locations, activities, associated
seismic survey activities). The report would also include estimates of
the number and nature of exposures that occurred above the harassment
threshold based on PSO observations, including an estimate of those on
the trackline but not detected.
Negligible Impact Analysis and Determination
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'' through harassment, NMFS considers other factors, such as the
likely nature of any responses (e.g., intensity, duration), the context
of any responses (e.g., critical reproductive time or location,
migration), as well as effects on habitat, and the likely effectiveness
of the 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' 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, or
ambient noise levels).
To avoid repetition, our analysis applies to all the species listed
in Table 2, given that NMFS expects the anticipated effects of the
proposed seismic survey to be similar in nature. Where there are
meaningful differences between species or stocks, or groups of species,
in anticipated individual responses to activities, impact of expected
take on the population due to differences in population status, or
impacts on habitat, NMFS has identified species-specific factors to
inform the analysis. As described above, we propose to authorize only
the takes estimated to occur outside of New Zealand territorial sea
(Tables 11, 12, 13 and 14); however, for the purposes of our negligible
impact analysis and determination, we consider the total number of
takes that are expected to occur as a result of the proposed survey,
including those within territorial sea. Thus, our negligible impact
analysis and determination accounts for the takes that are anticipated
to occur as a result of the proposed surveys during the portions of
those surveys that would occur within the territorial sea
(approximately 9 percent of the North Island 2-D survey, 1 percent of
the North Island 3-D survey, and 6 percent of the South Island 2-D
survey), though we do not propose to authorize the incidental take of
marine mammals during those portions of the proposed surveys.
NMFS does not anticipate that serious injury or mortality would
occur as a result of L-DEO's proposed survey, even in the absence of
proposed mitigation. Thus the proposed authorization does not authorize
any mortality. As discussed in the Potential Effects section, non-
auditory physical effects, stranding, and vessel strike are not
expected to occur.
We propose to authorize a limited number of instances of Level A
harassment of 21 marine mammal species (Tables 11, 12, 13 and 14).
However, we believe that any PTS incurred in marine mammals as a result
of the proposed activity would be in the form of only a small degree of
PTS, not total deafness, and would be unlikely to affect the fitness of
any individuals, because of the constant movement of both the Langseth
and of the marine mammals in the project area, as well as the fact that
the vessel is not expected to remain in any one area in which
individual marine mammals would be expected to concentrate for an
extended period of time (i.e., since the duration of exposure to loud
sounds will be relatively short). Also, as described above, we expect
that marine mammals would be likely to move away from a sound source
that represents an aversive stimulus, especially at levels that would
be expected to result in PTS, given sufficient notice of the Langseth's
approach due to the vessel's relatively low speed when conducting
seismic surveys. We expect that the majority of takes would be in the
form of short-term Level B behavioral harassment in the form of
temporary avoidance of the area or decreased foraging (if such activity
were occurring), reactions that are considered to be of low severity
and with no lasting biological consequences (e.g., Southall et al.,
2007).
Potential impacts to marine mammal habitat were discussed
previously in this document (see Potential Effects of the Specified
Activity on Marine Mammals and their Habitat). Marine mammal habitat
may be impacted by elevated sound levels, but these impacts would be
temporary. Feeding behavior is not likely to be significantly impacted,
as marine mammals appear to be less likely to exhibit behavioral
reactions or avoidance responses while engaged in feeding activities
(Richardson et al., 1995). Prey species are mobile and are broadly
distributed throughout the project area; therefore, marine mammals that
may be temporarily displaced during survey activities are expected to
be able to resume foraging once they have moved away from areas with
disturbing levels of underwater noise. Because of the temporary nature
of the disturbance, the availability of similar habitat and resources
in the surrounding area, and the lack of important or unique marine
mammal habitat, the impacts to marine mammals and the food sources that
they utilize are not expected to cause significant or long-term
consequences for individual marine mammals or their populations. In
addition, there are no mating or calving areas known to be biologically
important to marine mammals within the proposed project area.
The activity is expected to impact a small percentage of all marine
mammal stocks that would be affected by L-DEO's proposed survey (less
than 9 percent for dusky dolphin and less than 2 percent for all other
marine mammal species). Additionally, the acoustic ``footprint'' of the
proposed survey would be small relative to the ranges of the marine
mammals that would potentially be affected. Sound levels would increase
in the marine environment in a relatively small area surrounding the
vessel compared to the range of the marine mammals within the proposed
survey area.
The proposed mitigation measures are expected to reduce the number
and/or
[[Page 45151]]
severity of takes by allowing for detection of marine mammals in the
vicinity of the vessel by visual and acoustic observers, and by
minimizing the severity of any potential exposures via power downs and/
or shutdowns of the airgun array. Based on previous monitoring reports
for substantially similar activities that have been previously
authorized by NMFS, we expect that the proposed mitigation will be
effective in preventing at least some extent of potential PTS in marine
mammals that may otherwise occur in the absence of the proposed
mitigation.
The ESA-listed marine mammal species under our jurisdiction that
are likely to be taken by the proposed project include the southern
right, sei, fin, blue, and sperm whale (listed as endangered) and the
South Island Hector's dolphin (listed as threatened). We propose to
authorize very small numbers of takes for these species (Tables 11, 12,
13 and 14), relative to their population sizes, therefore we do not
expect population-level impacts to any of these species. The other
marine mammal species that may be taken by harassment during the
proposed survey are not listed as threatened or endangered under the
ESA. There is no designated critical habitat for any ESA-listed marine
mammals within the project area; and of the non-listed marine mammals
for which we propose to authorize take, none are considered
``depleted'' or ``strategic'' by NMFS under the MMPA.
NMFS concludes that exposures to marine mammal species and stocks
due to L-DEO's proposed survey would result in only short-term
(temporary and short in duration) effects to individuals exposed.
Animals may temporarily avoid the immediate area, but are not expected
to permanently abandon the area. Major shifts in habitat use,
distribution, or foraging success are not expected. NMFS does not
anticipate the proposed take estimates to impact annual rates of
recruitment or survival.
In summary and as described above, the following factors primarily
support our preliminary determination that the impacts resulting from
this activity are not expected to adversely affect the marine mammal
species or stocks through effects on annual rates of recruitment or
survival:
[ballot] No serious injury or mortality is anticipated or
authorized;
[ballot] The anticipated impacts of the proposed activity on marine
mammals would primarily be temporary behavioral changes due to
avoidance of the area around the survey vessel;
[ballot] The number of instances of PTS that may occur are expected
to be very small in number (Tables 11, 12, 13 and 14). Instances of PTS
that are incurred in marine mammals would be of a low level, due to
constant movement of the vessel and of the marine mammals in the area,
and the nature of the survey design (not concentrated in areas of high
marine mammal concentration);
[ballot] The availability of alternate areas of similar habitat
value for marine mammals to temporarily vacate the survey area during
the proposed survey to avoid exposure to sounds from the activity;
[ballot] The proposed project area does not contain known areas of
significance for mating or calving;
[ballot] The potential adverse effects on fish or invertebrate
species that serve as prey species for marine mammals from the proposed
survey would be temporary and spatially limited;
[ballot] The proposed mitigation measures, including visual and
acoustic monitoring, power-downs, and shutdowns, are expected to
minimize potential impacts to marine mammals.
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, NMFS preliminarily finds that the total marine
mammal take from the proposed activity will have a negligible impact on
all 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)(D) of the MMPA for specified
activities other than military readiness activities. The MMPA does not
define small numbers; 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. Tables 11, 12, 13 and 14 provide numbers of take by
Level A harassment and Level B harassment proposed for authorization.
These are the numbers we use for purposes of the small numbers
analysis.
The numbers of marine mammals that we propose for authorization to
be taken would be considered small relative to the relevant populations
(less than 9 percent for all species) for the species for which
abundance estimates are available. No known current worldwide or
regional population estimates are available for ten species under NMFS'
jurisdiction that could be incidentally taken as a result of the
proposed surveys: The pygmy right whale; pygmy sperm whale; True's
beaked whale; short-finned pilot whale; false killer whale; bottlenose
dolphin; short-beaked common dolphin; southern right whale dolphin;
Risso's dolphin; and spectacled porpoise.
NMFS has reviewed the geographic distributions and habitat
preferences of these species in determining whether the numbers of
takes proposed for authorization herein are likely to represent small
numbers. Pygmy right whales have a circumglobal distribution and occur
throughout coastal and oceanic waters in the Southern Hemisphere
(between 30 to 55[deg] South) (Jefferson et al., 2008). Pygmy sperm
whales occur in deep waters on the outer continental shelf and slope in
tropical to temperate waters of the Atlantic, Indian, and Pacific
Oceans. True's beaked whales occur in the Southern hemisphere from the
western Atlantic Ocean to the Indian Ocean to the waters of southern
Australia and possibly New Zealand (Jefferson et al., 2008). False
killer whales generally occur in deep offshore tropical to temperate
waters (between 50[deg] North to 50[deg] South) of the Atlantic,
Indian, and Pacific Oceans (Jefferson et al., 2008). Southern right
whale dolphins have a circumpolar distribution and generally occur in
deep temperate to sub-Antarctic waters in the Southern Hemisphere
(between 30 to 65[deg] South) (Jefferson et al., 2008). Short-finned
Pilot Whales are found in warm temperate to tropical waters throughout
the world, generally in deep offshore areas (Olson and Reilly, 2002).
Bottlenose dolphins are distributed worldwide through tropical and
temperate inshore, coastal, shelf, and oceanic waters (Leatherwood and
Reeves 1990, Wells and Scott 1999, Reynolds et al. 2000). Spectacled
porpoises are believed to have a range that is circumpolar in the sub-
Antarctic zone (with water temperatures of at least 1-10[deg] C)
(Goodall 2002). The Risso's dolphin is a widely-distributed species,
inhabiting primarily deep waters of the continental slope and outer
shelf (especially with steep bottom topography), from the tropics
through the temperate regions in both hemispheres (Kruse et al. 1999).
The short-beaked common dolphin is an oceanic species that is widely
distributed in tropical to cool temperate waters of the Atlantic and
Pacific
[[Page 45152]]
Oceans (Perrin 2002), from nearshore waters to thousands of kilometers
offshore.
Based on the broad spatial distributions and habitat preferences of
these species relative to the areas where the proposed surveys would
occur, NMFS preliminarily concludes that the authorized take of these
species likely represent small numbers relative to the affected
species' overall population sizes, though we are unable to quantify the
proposed take numbers as a percentage of population.
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.
Unmitigable Adverse Impact Analysis and Determination
There are no relevant subsistence uses of the affected marine
mammal stocks or species implicated by this action. Therefore, NMFS has
preliminarily determined that the total taking of affected species or
stocks would not have an unmitigable adverse impact on the availability
of such species or stocks for taking for subsistence purposes.
Endangered Species Act (ESA)
Section 7(a)(2) of the Endangered Species Act of 1973 (ESA: 16
U.S.C. 1531 et seq.) requires that each Federal agency insure that any
action it authorizes, funds, or carries out is not likely to jeopardize
the continued existence of any endangered or threatened species or
result in the destruction or adverse modification of designated
critical habitat. To ensure ESA compliance for the issuance of IHAs,
NMFS consults internally, in this case with the ESA Interagency
Cooperation Division, whenever we propose to authorize take for
endangered or threatened species.
The NMFS Permits and Conservation Division is proposing to
authorize the incidental take of six species of marine mammals which
are listed under the ESA (the southern right, sei, fin, blue, and sperm
whale and South Island Hector's dolphin). We have requested initiation
of Section 7 consultation with the Interagency Cooperation Division for
the issuance of this IHA. NMFS will conclude the ESA section 7
consultation prior to reaching a determination regarding the proposed
issuance of the authorization.
Proposed Authorization
As a result of these preliminary determinations, NMFS proposes to
issue an IHA to L-DEO for conducting a seismic survey in the Pacific
Ocean offshore New Zealand in 2017/2018, provided the previously
mentioned mitigation, monitoring, and reporting requirements are
incorporated. This section contains a draft of the IHA itself. The
wording contained in this section is proposed for inclusion in the IHA
(if issued).
1. This incidental harassment authorization (IHA) is valid for a
period of one year from the date of issuance.
2. This IHA is valid only for marine geophysical survey activity,
as specified in L-DEO's IHA application and using an array aboard the
R/V Langseth with characteristics specified in the IHA application, in
the Pacific Ocean offshore New Zealand.
3. General Conditions.
(a) A copy of this IHA must be in the possession of L-DEO, the
vessel operator and other relevant personnel, the lead protected
species observer (PSO), and any other relevant designees of L-DEO
operating under the authority of this IHA.
(b) The species authorized for taking are listed in Table 14. The
taking, by Level A and Level B harassment only, is limited to the
species and numbers listed in Table 14. Any taking exceeding the
authorized amounts listed in Table 14 is prohibited and may result in
the modification, suspension, or revocation of this IHA.
(c) The taking by serious injury or death of any species of marine
mammal is prohibited and may result in the modification, suspension, or
revocation of this IHA.
(d) During use of the airgun(s), if marine mammal species other
than those listed in Table 1 are detected by PSOs, the acoustic source
must be shut down to avoid unauthorized take.
(e) L-DEO shall ensure that the vessel operator and other relevant
vessel personnel are briefed on all responsibilities, communication
procedures, marine mammal monitoring protocol, operational procedures,
and IHA requirements prior to the start of survey activity, and when
relevant new personnel join the survey operations.
4. Mitigation Requirements.
The holder of this Authorization is required to implement the
following mitigation measures:
(a) L-DEO must use at least five dedicated, trained, NMFS-approved
Protected Species Observers (PSOs), including at least four visual PSOs
and one acoustic PSO. The PSOs must have no tasks other than to conduct
observational effort, record observational data, and communicate with
and instruct relevant vessel crew with regard to the presence of marine
mammals and mitigation requirements. PSO resumes shall be provided to
NMFS for approval.
(b) At least two PSOs must have a minimum of 90 days at-sea
experience working as PSOs during a high energy seismic survey, with no
more than eighteen months elapsed since the conclusion of the at-sea
experience. At least one of these must have relevant experience as a
visual PSO and at least one must have relevant experience as an
acoustic PSO. One ``experienced'' visual PSO shall be designated as the
lead for the entire protected species observation team. The lead shall
coordinate duty schedules and roles for the PSO team and serve as
primary point of contact for the vessel operator. The lead PSO shall
devise the duty schedule such that ``experienced'' PSOs are on duty
with those PSOs with appropriate training but who have not yet gained
relevant experience, to the maximum extent practicable.
(c) Visual Observation.
(i) During survey operations (e.g., any day on which use of the
acoustic source is planned to occur; whenever the acoustic source is in
the water, whether activated or not), two PSOs must be on duty and
conducting visual observations at all times during daylight hours
(i.e., from 30 minutes prior to sunrise through 30 minutes following
sunset) with the limited exception of meal times during which one PSO
may be on duty. PSOs shall monitor the entire extent of the estimated
Level B harassment zone (or, as far as they can see, if they cannot see
to the extent of the estimated Level B harassment zone).
(ii) Visual monitoring must begin not less than 30 minutes prior to
ramp-up, including for nighttime ramp-ups of the airgun array, and must
continue until one hour after use of the acoustic source ceases or
until 30 minutes past sunset.
(iii) Visual PSOs shall coordinate to ensure 360[deg] visual
coverage around the vessel from the most appropriate observation posts
and shall conduct visual observations using binoculars and the naked
eye while free from distractions and in a consistent, systematic, and
diligent manner.
(iv) Visual PSOs shall communicate all observations to the acoustic
PSO, including any determination by the PSO regarding species
identification, distance, and bearing and the degree of confidence in
the determination.
(v) Visual PSOs may be on watch for a maximum of four consecutive
hours
[[Page 45153]]
followed by a break of at least one hour between watches and may
conduct a maximum of 12 hours observation per 24 hour period.
(vi) During good conditions (e.g., daylight hours; Beaufort sea
state 3 or less), visual PSOs shall conduct observations when the
acoustic source is not operating for comparison of sighting rates and
behavior with and without use of the acoustic source and between
acquisition periods, to the maximum extent practicable.
(d) Acoustic Observation--The R/V Langseth must use a towed passive
acoustic monitoring (PAM) system, which must be monitored beginning at
least 30 minutes prior to ramp-up and at all times during use of the
acoustic source.
(i) One acoustic PSO (in addition to the four visual PSOs) must be
on board to operate and oversee PAM operations. Either the acoustic PSO
or a visual PSO with training in the PAM system must monitor the PAM
system at all times while airguns are operating, and when possible
during periods when the airguns are not operating, in shifts lasting no
longer than six hours.
(ii) Acoustic PSOs shall communicate all detections to visual PSOs,
when visual PSOs are on duty, including any determination by the PSO
regarding species identification, distance, and bearing and the degree
of confidence in the determination.
(iii) Survey activity may continue for brief periods of time if the
PAM system malfunctions or is damaged. Activity may continue for 30
minutes without PAM while the PAM operator diagnoses the issue. If the
diagnosis indicates that the PAM system must be repaired to solve the
problem, operations may continue for an additional two hours without
acoustic monitoring under the following conditions:
(A) Daylight hours and sea state is less than or equal to Beaufort
sea state 4;
(B) No marine mammals (excluding small delphinids) detected solely
by PAM in the exclusion zone in the previous two hours;
(C) NMFS is notified via email as soon as practicable with the time
and location in which operations began without an active PAM system;
and
(D) Operations with an active acoustic source, but without an
operating PAM system, do not exceed a cumulative total of four hours in
any 24 hour period.
(e) Exclusion Zone and buffer zone--PSOs shall establish and
monitor a 500 m exclusion zone (EZ) and 1,000 m buffer zone. The zones
shall be based upon radial distance from any element of the airgun
array (rather than being based on the center of the array or around the
vessel itself). During use of the acoustic source, occurrence of marine
mammals outside the EZ but within 1,000 m from any element of the
airgun array shall be communicated to the operator to prepare for
potential further mitigation measures as described below. During use of
the acoustic source, occurrence of marine mammals within the EZ, or on
a course to enter the EZ, shall trigger further mitigation measures as
described below.
(i) Ramp-up--A ramp-up procedure, involving a step-wise increase in
the number of airguns firing and total array volume until all
operational airguns are activated and the full volume is achieved, is
required at all times as part of the activation of the acoustic source,
including following a power down or shutdown of the array, except as
described under 4.(e)(v). Ramp-up shall begin by activating a single
airgun of the smallest volume in the array and shall continue in stages
by doubling the number of active elements at the commencement of each
stage, with each stage of approximately the same duration.
(ii) If the airgun array has been powered down or shut down due to
a marine mammal detection, ramp-up shall not occur until all marine
mammals have cleared the EZ. A marine mammal is considered to have
cleared the EZ if:
(A) It has been visually observed to have left the EZ; or
(B) It has not been observed within the EZ, for 15 minutes (in the
case of small odontocetes and pinnipeds) or for 30 minutes (in the case
of mysticetes and large odontocetes including sperm, pygmy sperm, dwarf
sperm, and beaked whales).
(iii) Thirty minutes of pre-clearance observation of the 500 m EZ
and 1,000 m buffer zone are required prior to ramp-up for any power
down, shutdown, or combination of power down and shutdown of longer
than 30 minutes. This pre-clearance period may occur during any vessel
activity. If any marine mammal (including delphinids) is observed
within or approaching the 500 m EZ during the 30 minute pre-clearance
period, ramp-up may not begin until the animal(s) has been observed
exiting the buffer zone or until an additional time period has elapsed
with no further sightings (i.e., 15 minutes for small odontocetes and
pinnipeds, and 30 minutes for mysticetes and large odontocetes
including sperm, pygmy sperm, dwarf sperm, and beaked whales).
(iv) During ramp-up, PSOs shall monitor the 500 m EZ and 1,000 m
buffer zone. Ramp-up may not be initiated if any marine mammal
(including delphinids) is observed within or approaching the 500 m EZ.
If a marine mammal is observed within or approaching the 500 m EZ
during ramp-up, a power down or shutdown shall be implemented as though
the full array were operational. Ramp-up may not begin again until the
animal(s) has been observed exiting the 500 m EZ or until an additional
time period has elapsed with no further sightings (i.e., 15 minutes for
small odontocetes and pinnipeds, and 30 minutes for mysticetes and
large odontocetes including sperm, pygmy sperm, dwarf sperm, and beaked
whales).
(v) Ramp-up shall only occur at night and at times of poor
visibility where operational planning cannot reasonably avoid such
circumstances. Ramp-up may occur at night and during poor visibility if
the 500 m EZ and 1,000 m buffer zone have been continually monitored by
visual PSOs for 30 minutes prior to ramp-up with no marine mammal
detections and if acoustic monitoring has occurred for 30 minutes prior
to ramp-up with no acoustic detections during that period.
(vi) If the airgun array has been shut down for reasons other than
mitigation (e.g., mechanical difficulty) for a period of less than 30
minutes, it may be activated again without ramp-up if PSOs have
maintained constant visual and acoustic observation and no visual
detections of any marine mammal have occurred within the buffer zone
and no acoustic detections have occurred.
(vii) The vessel operator must notify a designated PSO of the
planned start of ramp-up as agreed-upon with the lead PSO; the
notification time should not be less than 60 minutes prior to the
planned ramp-up. A designated PSO must be notified again immediately
prior to initiating ramp-up procedures and the operator must receive
confirmation from the PSO to proceed.
(f) Power Down Requirements--L-DEO shall power down the airgun
array if a PSO detects a marine mammal within, approaching, or entering
the 500 m EZ. A power down involves a decrease in the number of
operational airguns. During a power down, one 40-in\3\ airgun shall be
continuously operated.
(i) Any PSO on duty has the authority to call for power down of the
airgun array (visual PSOs on duty should be in agreement on the need
for power down before requiring such action). When there is certainty
regarding the need for mitigation action on the basis of either visual
or acoustic detection alone, the relevant PSO(s) must call for such
action immediately.
[[Page 45154]]
(ii) When both visual and acoustic PSOs are on duty, all detections
must be immediately communicated to the remainder of the on-duty PSO
team for potential verification of visual observations by the acoustic
PSO or of acoustic detections by visual PSOs and initiation of dialogue
as necessary.
(iii) The operator must establish and maintain clear lines of
communication directly between PSOs on duty and crew controlling the
airgun array to ensure that power down commands are conveyed swiftly
while allowing PSOs to maintain watch.
(iv) When power down is called for by a PSO, the power down must
occur and any dispute resolved only following power down.
(v) The power down requirement is waived for dolphins of the
following genera: Tursiops, Delphinus and Lissodelphis. This power down
waiver only applies if animals are traveling, including approaching the
vessel. If animals are stationary and the vessel approaches the
animals, the power down requirement applies. If there is uncertainty
regarding identification (i.e., whether the observed animal(s) belongs
to the group described above) or whether the animals are traveling,
power down must be implemented.
(vi) Upon implementation of a power down, the source may be
reactivated under the conditions described at 4(e). Where there is no
relevant zone (e.g., power down due to observation of a calf), a 30-
minute clearance period must be observed following the last observation
of the animal(s).
(vii) When only the acoustic PSO is on duty and a detection is
made, if there is uncertainty regarding species identification or
distance to the vocalizing animal(s), the airgun array must be powered
down as a precaution.
(viii) Power down shall occur for no more than a maximum of 30
minutes at any given time. If, after 30 minutes of the array being
powered down, marine mammals have not cleared the 500 m Exclusion Zone
as described under 4(e)(iv), the array shall be shut down. Operation of
the single 40-in\3\ airgun (i.e., a power-down state) shall not occur
for any purpose other than in response to a marine mammal in the
exclusion zone (pursuant to relevant requirements herein).
(g) Shutdown requirements--An exclusion zone of 100 m for the
single 40-in\3\ airgun shall be established and monitored by PSOs. If a
marine mammal is observed within, entering, or approaching the 100 m
exclusion zone for the single 40-in\3\ airgun, whether during
implementation of a power down or during operation of the full airgun
array, all airguns including the 40-in\3\ airgun shall be shut down.
(h) If, after 30 minutes of the array being powered down, marine
mammals have not cleared the 500 m Exclusion Zone as described under
4(e)(iv), the full array shall be shut down.
(i) Upon implementation of a shutdown, the source may be
reactivated under the conditions described at 4(e).
(ii) Measures described for power downs under 4(f)(i-v) shall also
apply in the case of a shutdown.
(iii) Shutdown of the acoustic source is required upon observation
of a large whale (i.e., sperm whale or any baleen whale) with calf at
any distance, with ``calf'' defined as an animal less than two-thirds
the body size of an adult observed to be in close association with an
adult. Ramp up shall not begin until the whale with calf has not been
observed for at least 30 minutes, at any distance.
(iv) Shutdown of the acoustic source is required upon observation
of a beaked whale or kogia spp., at any distance. Ramp up shall not
begin until the beaked whale or kogia has not been observed for at
least 30 minutes, at any distance.
(v) Shutdown of the acoustic source is required upon observation of
a Hector's dolphin, at any distance, during the North Island 2-D survey
and North Island 3-D survey. Ramp up shall not begin until the Hector's
dolphin has not been observed for at least 15 minutes, at any distance.
(i) Vessel Strike Avoidance--Vessel operator and crew must maintain
a vigilant watch for all marine mammals and slow down or stop the
vessel or alter course to avoid striking any marine mammal. These
requirements do not apply in any case where compliance would create an
imminent and serious threat to a person or vessel or to the extent that
a vessel is restricted in its ability to maneuver and, because of the
restriction, cannot comply. A visual observer aboard the vessel must
monitor a vessel strike avoidance zone around the vessel according to
the parameters stated below. Visual observers monitoring the vessel
strike avoidance zone can be either third-party observers or crew
members, but crew members responsible for these duties must be provided
sufficient training to distinguish marine mammals from other phenomena.
Vessel strike avoidance measures shall be followed during surveys and
while in transit.
(i) The vessel must maintain a minimum separation distance of 100 m
from large whales (i.e., baleen whales and sperm whales). The following
avoidance measures must be taken if a large whale is within 100 m of
the vessel:
(A) The vessel must reduce speed and shift the engine to neutral,
and must not engage the engines until the whale has moved outside of
the vessel's path and the minimum separation distance has been
established.
(B) If the vessel is stationary, the vessel must not engage engines
until the whale(s) has moved out of the vessel's path and beyond 100 m.
(ii) The vessel must maintain a minimum separation distance of 50 m
from all other marine mammals, with an exception made for animals
described in 4(f)(v) that approach the vessel. If an animal is
encountered during transit, the vessel shall attempt to remain parallel
to the animal's course, avoiding excessive speed or abrupt changes in
course.
(iii) Vessel speeds must be reduced to 10 knots or less when
mother/calf pairs, pods, or large assemblages of cetaceans are observed
near the vessel.
(j) Miscellaneous Protocols.
(i) The airgun array must be deactivated when not acquiring data or
preparing to acquire data, except as necessary for testing. Unnecessary
use of the acoustic source shall be avoided. Notified operational
capacity (not including redundant backup airguns) must not be exceeded
during the survey, except where unavoidable for source testing and
calibration purposes. All occasions where activated source volume
exceeds notified operational capacity must be noticed to the PSO(s) on
duty and fully documented. The lead PSO must be granted access to
relevant instrumentation documenting acoustic source power and/or
operational volume.
(ii) Testing of the acoustic source involving all elements requires
normal mitigation protocols (e.g., ramp-up). Testing limited to
individual source elements or strings does not require ramp-up but does
require pre-clearance.
5. Monitoring Requirements.
The holder of this Authorization is required to conduct marine
mammal monitoring during survey activity. Monitoring shall be conducted
in accordance with the following requirements:
(a) The operator must provide bigeye binoculars (e.g., 25 x 150;
2.7 view angle; individual ocular focus; height control) of appropriate
quality (i.e., Fujinon or equivalent) solely for PSO use. These shall
be pedestal-mounted on the deck at the most appropriate vantage point
that provides for optimal sea surface observation, PSO safety, and safe
operation of the vessel. The
[[Page 45155]]
operator must also provide a night-vision device suited for the marine
environment for use during nighttime ramp-up pre-clearance, at the
discretion of the PSOs. At minimum, the device should feature automatic
brightness and gain control, bright light protection, infrared
illumination, and optics suited for low-light situations.
(b) PSOs must also be equipped with reticle binoculars (e.g., 7 x
50) of appropriate quality (i.e., Fujinon or equivalent), GPS, digital
single-lens reflex camera of appropriate quality (i.e., Canon or
equivalent), compass, and any other tools necessary to adequately
perform necessary tasks, including accurate determination of distance
and bearing to observed marine mammals.
(c) PSO Qualifications.
(i) PSOs must have successfully completed relevant training,
including completion of all required coursework and passing a written
and/or oral examination developed for the training program.
(ii) PSOs must have successfully attained a bachelor's degree from
an accredited college or university with a major in one of the natural
sciences and a minimum of 30 semester hours or equivalent in the
biological sciences and at least one undergraduate course in math or
statistics. The educational requirements may be waived if the PSO has
acquired the relevant skills through alternate experience. Requests for
such a waiver must include written justification. Alternate experience
that may be considered includes, but is not limited to (1) secondary
education and/or experience comparable to PSO duties; (2) previous work
experience conducting academic, commercial, or government-sponsored
marine mammal surveys; or (3) previous work experience as a PSO. The
PSO should demonstrate good standing and consistently good performance
of PSO duties.
(d) Data Collection--PSOs must use standardized data forms, whether
hard copy or electronic. PSOs shall record detailed information about
any implementation of mitigation requirements, including the distance
of animals to the acoustic source and description of specific actions
that ensued, the behavior of the animal(s), any observed changes in
behavior before and after implementation of mitigation, and if shutdown
was implemented, the length of time before any subsequent ramp-up of
the acoustic source to resume survey. If required mitigation was not
implemented, PSOs should submit a description of the circumstances.
NMFS requires that, at a minimum, the following information be
reported:
(i) PSO names and affiliations.
(ii) Dates of departures and returns to port with port name.
(iii) Dates and times (Greenwich Mean Time) of survey effort and
times corresponding with PSO effort.
(iv) Vessel location (latitude/longitude) when survey effort begins
and ends; vessel location at beginning and end of visual PSO duty
shifts.
(v) Vessel heading and speed at beginning and end of visual PSO
duty shifts and upon any line change.
(vi) Environmental conditions while on visual survey (at beginning
and end of PSO shift and whenever conditions change significantly),
including wind speed and direction, Beaufort sea state, Beaufort wind
force, swell height, weather conditions, cloud cover, sun glare, and
overall visibility to the horizon.
(vii) Factors that may be contributing to impaired observations
during each PSO shift change or as needed as environmental conditions
change (e.g., vessel traffic, equipment malfunctions).
(viii) Survey activity information, such as acoustic source power
output while in operation, number and volume of airguns operating in
the array, tow depth of the array, and any other notes of significance
(i.e., pre-ramp-up survey, ramp-up, shutdown, testing, shooting, ramp-
up completion, end of operations, streamers, etc.).
(ix) If a marine mammal is sighted, the following information
should be recorded:
(A) Watch status (sighting made by PSO on/off effort,
opportunistic, crew, alternate vessel/platform).
(B) PSO who sighted the animal.
(C) Time of sighting.
(D) Vessel location at time of sighting.
(E) Water depth.
(F) Direction of vessel's travel (compass direction).
(G) Direction of animal's travel relative to the vessel.
(H) Pace of the animal.
(I) Estimated distance to the animal and its heading relative to
vessel at initial sighting.
(J) Identification of the animal (e.g., genus/species, lowest
possible taxonomic level, or unidentified); also note the composition
of the group if there is a mix of species.
(K) Estimated number of animals (high/low/best).
(L) Estimated number of animals by cohort (adults, yearlings,
juveniles, calves, group composition, etc.).
(M) Description (as many distinguishing features as possible of
each individual seen, including length, shape, color, pattern, scars or
markings, shape and size of dorsal fin, shape of head, and blow
characteristics).
(N) Detailed behavior observations (e.g., number of blows, number
of surfaces, breaching, spyhopping, diving, feeding, traveling; as
explicit and detailed as possible; note any observed changes in
behavior).
(O) Animal's closest point of approach (CPA) and/or closest
distance from the center point of the acoustic source;.
(P) Platform activity at time of sighting (e.g., deploying,
recovering, testing, shooting, data acquisition, other).
(Q) Description of any actions implemented in response to the
sighting (e.g., delays, shutdown, ramp-up, speed or course alteration,
etc.); time and location of the action should also be recorded.
(x) If a marine mammal is detected while using the PAM system, the
following information should be recorded:
(A) An acoustic encounter identification number, and whether the
detection was linked with a visual sighting.
(B) Time when first and last heard.
(C) Types and nature of sounds heard (e.g., clicks, whistles,
creaks, burst pulses, continuous, sporadic, strength of signal, etc.).
(D) Any additional information recorded such as water depth of the
hydrophone array, bearing of the animal to the vessel (if
determinable), species or taxonomic group (if determinable), and any
other notable information.
6. Reporting.
(a) L-DEO shall submit a draft comprehensive report on all
activities and monitoring results within 90 days of the completion of
the survey or expiration of the IHA, whichever comes sooner. The report
must describe all activities conducted and sightings of marine mammals
near the activities, must provide full documentation of methods,
results, and interpretation pertaining to all monitoring, and must
summarize the dates and locations of survey operations and all marine
mammal sightings (dates, times, locations, activities, associated
survey activities). Geospatial data regarding locations where the
acoustic source was used must be provided. In addition to the report,
all raw observational data shall be made available to NMFS. The report
must summarize the data collected as required under condition 5(d) of
this IHA. The report must also provide an estimate of the number (by
species) of marine mammals with known exposures to seismic survey
activity at received levels greater than or equal to thresholds for
Level A and Level B harassment (based on visual
[[Page 45156]]
observation) including an estimate of those on the trackline but not
detected. The draft report must be accompanied by a certification from
the lead PSO as to the accuracy of the report, and the lead PSO may
submit directly to NMFS a statement concerning implementation and
effectiveness of the required mitigation and monitoring. A final report
must be submitted within 30 days following resolution of any comments
from NMFS on the draft report.
(b) Reporting injured or dead marine mammals:
(i) In the event that the specified activity clearly causes the
take of a marine mammal in a manner not permitted by this IHA, such as
serious injury or mortality, L-DEO shall immediately cease the
specified activities and immediately report the incident to the NMFS
Office of Protected Resources (301-427-8401) and the New Zealand
Department of Conservation (0800-362-468). The report must include the
following information:
(A) Time, date, and location (latitude/longitude) of the incident;
(B) Vessel's speed during and leading up to the incident;
(C) Description of the incident;
(D) Status of all sound source use in the 24 hours preceding the
incident;
(E) Water depth;
(F) Environmental conditions (e.g., wind speed and direction,
Beaufort sea state, cloud cover, and visibility);
(G) Description of all marine mammal observations in the 24 hours
preceding the incident;
(H) Species identification or description of the animal(s)
involved;
(I) Fate of the animal(s); and
(J) Photographs or video footage of the animal(s).
Activities shall not resume until NMFS is able to review the
circumstances of the prohibited take. NMFS will work with L-DEO to
determine what measures are necessary to minimize the likelihood of
further prohibited take and ensure MMPA compliance. L-DEO may not
resume their activities until notified by NMFS.
(ii) In the event that L-DEO discovers an injured or dead marine
mammal, and the lead observer 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), L-DEO shall immediately report
the incident to the NMFS Office of Protected Resources (301-427-8401)
and the New Zealand Department of Conservation (0800-362-468). The
report must include the same information identified in condition
6(b)(i) of this IHA. Activities may continue while NMFS reviews the
circumstances of the incident. NMFS will work with L-DEO to determine
whether additional mitigation measures or modifications to the
activities are appropriate.
(iii) In the event that L-DEO discovers an injured or dead marine
mammal, and the lead observer determines that the injury or death is
not associated with or related to the specified activities (e.g.,
previously wounded animal, carcass with moderate to advanced
decomposition, or scavenger damage), L-DEO shall report the incident to
the NMFS Office of Protected Resources (301-427-8401) and the New
Zealand Department of Conservation (0800-362-468) within 24 hours of
the discovery. L-DEO shall provide photographs or video footage or
other documentation of the sighting to NMFS.
7. This Authorization may be modified, suspended or withdrawn if
the holder fails to abide by the conditions prescribed herein, or if
NMFS determines the authorized taking is having more than a negligible
impact on the species or stock of affected marine mammals.
Dated: September 22, 2017.
Catherine Marzin,
Acting Deputy Director, Office of Protected Resources, National Marine
Fisheries Service.
[FR Doc. 2017-20696 Filed 9-26-17; 8:45 am]
BILLING CODE 3510-22-P