[Federal Register: April 24, 2006 (Volume 71, Number 78)]
[Notices]
[Page 20986-21003]
From the Federal Register Online via GPO Access [wais.access.gpo.gov]
[DOCID:fr24ap06-44]
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DEPARTMENT OF COMMERCE
National Oceanic and Atmospheric Administration
[I.D. 011806L]
Small Takes of Marine Mammals Incidental to Specified Activities;
Rim of the Pacific (RIMPAC) Antisubmarine Warfare (ASW) Exercise
Training Events Within the Hawaiian Islands Operating Area (OpArea)
AGENCY: National Marine Fisheries Service (NMFS), National Oceanic and
Atmospheric Administration (NOAA), Commerce.
ACTION: Notice; receipt of application and proposed incidental take
authorization; request for comments.
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SUMMARY: NMFS has received an application from the U.S. Navy (Navy) for
an Incidental Harassment Authorization (IHA) to take marine mammals, by
harassment, incidental to conducting RIMPAC ASW training events, in
which submarines, surface ships, and aircraft from the United States
and multiple foreign nations participate in ASW training exercises,
utilizing mid-frequency sonar (1 kilohertz (kHz) to 10 kHz), in the
U.S. Navy's Hawaiian Operating Area (OpArea) in the summer of 2006.
Pursuant to the Marine Mammal Protection Act (MMPA), NMFS is requesting
comments on its proposal to issue an authorization to the Navy to
incidentally harass several species of marine mammals during the
training exercises.
DATES: Comments and information must be received no later than May 24,
2006.
ADDRESSES: Comments on the application should be addressed to Steve
Leathery, Chief, Permits, Conservation and Education Division, Office
of Protected Resources, National Marine Fisheries Service, 1315 East-
West Highway, Silver Spring, MD 20910-3225. The mailbox address for
providing email comments is PR1.011806L@noaa.gov. NMFS is not
responsible for e-mail comments sent to addresses other than the one
provided here. Comments sent via e-mail, including all attachments,
must not exceed a 10-megabyte file size.
A copy of the application containing a list of the references used
in this document may be obtained by writing to the address specified
above, telephoning the contact listed below (see FOR FURTHER
INFORMATION CONTACT), or visiting the internet at: http://www.nmfs.noaa.gov/pr/permits/incidental.htm
.
Documents cited in this notice may be viewed, by appointment,
during regular business hours, at the aforementioned address.
In March, 2006, the Navy prepared a revised 2006 Supplement on the
2002 Programmatic Environmental Assessment on RIMPAC. That document
will be posted on the Navy's website (http://www.smdcen.us/rimpac06/)
concurrently with this notice and the Navy will be accepting public
comments.
The Navy has also prepared a Draft Environmental Impact Statement
(DEIS) for its Undersea Warfare Training Range (USWTR), which contains
detailed supporting information for some of the issues discussed in
this document and may be viewed at: http://projects.earthtech.com.
NMFS' Ocean Acoustics Program has made additional information and
references relating to the effects of anthropogenic sound available on
the NMFS website at: http://www.nmfs.noaa.gov/pr/acoustics/bibliography.htm
.
FOR FURTHER INFORMATION CONTACT: Jolie Harrison, Office of Protected
Resources, NMFS, (301) 713-2289, ext 166.
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 to allow, upon request, the
incidental, but not intentional, taking of marine mammals
[[Page 20987]]
by U.S. citizens who engage in a specified activity (other than
commercial fishing) within a specified geographical region if certain
findings are made and either regulations are issued or, if the taking
is limited to harassment, a notice of a proposed authorization is
provided to the public for review.
Authorization 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, and that 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.''
Section 101(a)(5)(D) of the MMPA established an expedited process
by which citizens of the United States can apply for an authorization
to incidentally take small numbers of marine mammals by harassment. The
National Defense Authorization Act of 2004 (NDAA) (Public Law 108-136)
removed the ``small numbers'' limitation and amended the definition of
``harassment'' as it applies to a ``military readiness activity'' to
read as follows:
(i) any act that injures or has the significant potential to
injure a marine mammal or marine mammal stock in the wild [Level A
Harassment]; or (ii) any act that disturbs or is likely to disturb a
marine mammal or marine mammal stock in the wild by causing
disruption of natural behavioral patterns, including, but not
limited to, migration, surfacing, nursing, breeding, feeding, or
sheltering, to a point where such behavioral patterns are abandoned
or significantly altered [Level B Harassment]
Section 101(a)(5)(D) establishes a 45-day time limit for NMFS
review of an application followed by a 30-day public notice and comment
period on any proposed authorizations for the incidental harassment of
marine mammals. Within 45 days of the close of the comment period, NMFS
must either issue or deny issuance of the authorization.
Summary of Request
NMFS received an application from the Navy for the taking, by
harassment, of several species of marine mammals incidental to
conducting RIMPAC ASW training events, in which submarines, surface
ships, and aircraft from the United States and multiple foreign nations
participate in ASW training exercises, in the OpArea, in the summer of
2006. The RIMPAC ASW exercises are considered a military readiness
activity. Based on discussions between the agencies regarding
behavioral thresholds and mitigation and monitoring, the Navy submitted
a modified application on March 16, 2006.
Description of the Activity
RIMPAC 2006 ASW activities are scheduled to take place from June
26, 2006, to about July 28, 2006, with ASW training events planned on
21 days. The OpArea is approximately 210,000 square nautical miles
(nm), however, nearly all RIMPAC ASW training would occur in the six
areas delineated in Figure 2-1 in the Navy's application (approximate
46,000 square nm). ASW events typically rotate between these six
modeled areas. Sonar training exercises will occur within these areas
for the most part; however, sonar may be operated briefly for battle
preparation while forces are in transit from one of the modeled areas
to another. These six areas were used for analysis as being
representative of the marine mammal habitats and the bathymetric,
seabed, wind speed, and sound velocity profile conditions within the
entire OpArea. For purposes of this analysis, all likely RIMPAC ASW
events were modeled as occurring in these six areas.
As a combined force during the exercises, submarines, surface
ships, and aircraft will conduct ASW against opposition submarine
targets. Submarine targets include real submarines, target drones that
simulate the operations of an actual submarine, and virtual submarines
interjected into the training events by exercise controllers. ASW
training events are complex and highly variable. For RIMPAC, the
primary event involves a Surface Action Group (SAG), consisting of one
to five surface ships equipped with sonar, with one or more
helicopters, and a P-3 aircraft searching for one or more submarines.
There will be approximately four SAGs for RIMPAC 2006. For the purposes
of analysis, each event in which a SAG participates is counted as an
ASW operation. There will be approximately 44 ASW operations during
RIMPAC with an average event length of approximately 12 hours.
One or more ASW events may occur simultaneously within the OpArea.
Each event was identified and modeled separately. If a break of more
than 1 hour in ASW operations occurred, then the subsequent event was
modeled as a separate event. Training event durations ranged from 2
hours to 24 hours. A total of 532 training hours were modeled for
RIMPAC acoustic exposures. This total includes all potential ASW
training that is expected to occur during RIMPAC.
Active Acoustic Sources
Tactical military sonars are designed to search for, detect,
localize, classify, and track submarines. There are two types of
sonars, passive and active. Passive sonars only listen to incoming
sounds and, since they do not emit sound energy in the water, lack the
potential to acoustically affect the environment. Active sonars
generate and emit acoustic energy specifically for the purpose of
obtaining information concerning a distant object from the sound energy
reflected back from that object.
Modern sonar technology has developed a multitude of sonar sensor
and processing systems. In concept, the simplest active sonars emit
omnidirectional pulses (``pings'') and time the arrival of the
reflected echoes from the target object to determine range. More
sophisticated active sonar emits an omnidirectional ping and then
rapidly scans a steered receiving beam to provide directional, as well
as range, information. More advanced sonars transmit multiple preformed
beams, listening to echoes from several directions simultaneously and
providing efficient detection of both direction and range.
The tactical military sonars to be deployed in RIMPAC are designed
to detect submarines in tactical operational scenarios. This task
requires the use of the sonar mid-frequency (MF) range (1 kilohertz
[kHz] to 10 kHz) predominantly.
The types of tactical acoustic sources that would be used in
training events during RIMPAC are discussed in the following
paragraphs. For more information regarding how the Navy's determined
which sources should not be included in their analysis, see the
Estimates of Take Section later in this document.
Surface Ship Sonars - A variety of surface ships participate in
RIMPAC, including guided missile cruisers, destroyers, guided missile
destroyers, and frigates. Some ships (e.g., aircraft carriers) do not
have any onboard active sonar systems, other than fathometers. Others,
like guided missile cruisers, are equipped with active as well as
passive sonars for submarine detection and tracking. For purposes of
the analysis, all surface ship sonars were modeled as equivalent to
SQS-53 having the nominal source level of 235 decibels (dB) re 1mPa2-s
(SEL). Since the SQS-
[[Page 20988]]
53 hull mounted sonar is the U.S. Navy's most powerful surface ship
hull mounted sonar, modeling this source is a conservative assumption
tending towards an overestimation of potential effects (although, the
conservativeness is offset some by the fact that the Navy did not model
for any of the times (though brief and infrequent) that they may use a
source level higher than 235 dB). Sonar ping transmission durations
were modeled as lasting 1 second per ping and omnidirectional, which is
a conservative assumption that overestimates potential exposures, since
actual ping durations will be less than 1 second. The SQS-53 hull
mounted sonar transmits at center frequencies of 2.6 kHz and 3.3 kHz.
Submarine Sonars - Submarine sonars can be used to detect and
target enemy submarines and surface ships. However, submarine active
sonar use is very rare in the planned RIMPAC exercises, and, when used,
very brief. Therefore, use of active sonar by submarines is unlikely to
have any effect on marine mammals, and it was not modeled for RIMPAC
2006.
Aircraft Sonar Systems - Aircraft sonar systems that would operate
during RIMPAC include sonobuoys and dipping sonar. Sonobuoys may be
deployed by P-3 aircraft or helicopters; dipping sonars are used by
carrier-based helicopters. A sonobuoy is an expendable device used by
aircraft for the detection of underwater acoustic energy and for
conducting vertical water column temperature measurements. Most
sonobuoys are passive, but some can generate active acoustic signals as
well. Dipping sonar is an active or passive sonar device lowered on
cable by helicopters to detect or maintain contact with underwater
targets. During RIMPAC, these systems active modes are only used
briefly for localization of contacts and are not used in primary search
capacity. Because active mode dipping sonar use is very brief, it is
extremely unlikely its use would have any effect on marine mammals. The
AN/AQS 13 (dipping sonar) used by carrier based helicopters was
determined in the Environmental Assessment/Overseas Environmental
Assessment of the SH-60R Helicopter/ALFS Test Program, October 1999,
not to be problematic due to its limited use and very short pulse
length. Therefore, the aircraft sonar systems were not modeled for
RIMPAC 2006.
Torpedoes - Torpedoes are the primary ASW weapon used by surface
ships, aircraft, and submarines. The guidance systems of these weapons
can be autonomous or electronically controlled from the launching
platform through an attached wire. The autonomous guidance systems are
acoustically based. They operate either passively, exploiting the
emitted sound energy by the target, or actively, ensonifying the target
and using the received echoes for guidance. All torpedoes used for ASW
during RIMPAC would be located in the range area managed by Pacific
Missile Range Facility (PMRF) and would be non-explosive and recovered
after use.
Acoustic Device Countermeasures (ADC) - ADCs are, in effect,
submarine simulators that make noise to act as decoys to avert
localization and/or torpedo attacks. Previous classified analysis has
shown that, based on the operational characteristics (source output
level and/or frequency) of these acoustic sources, the potential to
affect marine mammals was unlikely, and therefore they were not modeled
for RIMPAC 2006.
Training Targets - ASW training targets are used to simulate target
submarines. They are equipped with one or a combination of the
following devices: (1) acoustic projectors emanating sounds to simulate
submarine acoustic signatures; (2) echo repeaters to simulate the
characteristics of the echo of a particular sonar signal reflected from
a specific type of submarine; and (3) magnetic sources to trigger
magnetic detectors. Based on the operational characteristics (source
output level and/or frequency) of these acoustic sources, the potential
to affect marine mammals is unlikely, and therefore they were not
modeled for RIMPAC 2006.
Range Sources - Range pingers are active acoustic devices that
allow each of the in-water platforms on the range (e.g., ships,
submarines, target simulators, and exercise torpedoes) to be tracked by
the range transducer nodes. In addition to passively tracking the
pinger signal from each range participant, the range transducer nodes
also are capable of transmitting acoustic signals for a limited set of
functions. These functions include submarine warning signals, acoustic
commands to submarine target simulators (acoustic command link), and
occasional voice or data communications (received by participating
ships and submarines on range). Based on the operational
characteristics (source output level and/or frequency) of these
acoustic sources, the potential to affect marine mammals is unlikely,
and therefore they were not modeled for RIMPAC 2006.
For detailed information regarding the proposed activity, please
see the Navy's application and the associated Environmental Assessment
(EA) (see ADDRESSES).
Description of Marine Mammals Potentially Affected by the Activity
There are 27 marine mammal species with possible or confirmed
occurrence in the Navy's OpArea (Table 1): 25 cetacean species (whales,
dolphins, and porpoises) and 2 pinnipeds (seals). In addition, five
species of sea turtles are known to occur in the OpArea.
The most abundant marine mammals are rough-toothed dolphins, dwarf
sperm whales, and Fraser's dolphins. The most abundant large whales are
sperm whales. There are three seasonally migrating baleen whale species
that winter in Hawaiian waters: minke, fin, and humpback whales.
Humpback whales utilize Hawaiian waters as a major breeding ground
during winter and spring (November through April), but should not be
present during the RIMPAC exercise, which takes place in July. Because
definitive information on the other two migrating species is lacking,
their possible presence during the July timeframe is assumed, although
it is considered unlikely. Seven marine mammal species listed as
federally endangered under the Endangered Species Act (ESA) occur in
the area: the humpback whale, North Pacific right whale, sei whale, fin
whale, blue whale, sperm whale, and Hawaiian monk seal.
The Navy has used data compiled from available sighting records,
literature, satellite tracking, and stranding and bycatch data to
identify the species of marine mammals present in the OpArea. A
combination of inshore survey data (within 25 nm; Mobley et al., 2000)
and offshore data (from 25 nm offshore out to the U.S. EEZ, Barlow
2003) was used to estimate the density and abundance of marine mammals
within the OpArea (Table 1). Additional information regarding the
status and distribution of the 27 marine mammal species that occur in
the OpArea may be found in the Navy's application and the associated EA
(See ADDRESSES) and in NMFS' Stock Assessment Reports, which are
available at: http://www.nmfs.noaa.gov/pr/PR2/Stock_Assessment_Program/individual_sars.html
.
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Potential Effects on Marine Mammals
The Navy has requested an IHA for the take, by harassment, of
marine mammals incidental to RIMPAC ASW exercises in the OpArea.
Section 101(a)(5)(D) of the MMPA, the section pursuant to which IHAs
are issued, may not be used to authorize mortality or serious injury
leading to mortality. The Navy's analysis of the RIMPAC ASW exercises
concluded that no mortality or serious injury leading to mortality
would result from the proposed activities. However, NMFS believes,
based on our interpretation of the limited available data bearing on
this point, that some marine mammals may react to mid-frequency sonar,
at received levels lower than those thought to cause direct physical
harm, with behaviors that may, in some circumstances, lead to
physiological harm, stranding, or, potentially, death. Therefore, NMFS
is proposing to require additional mitigation and monitoring measures
that were not originally proposed in the Navy's application to ensure
(in addition to the standard statutory requirement to effect the
``least practicable adverse impact upon the affected species or stoc'')
that mortality or serious injury leading to mortality does not result
from the proposed activities. Below, NMFS describes the potential
effects on marine mammals of exposure to tactical sonar. However, due
to the mitigation and monitoring required by this IHA, NMFS does not
expect marine mammals to be exposed to sound of the strength or
duration necessary to potentially induce the more severe of the effects
discussed below.
Metrics Used in Acoustic Effect Discussions
This section includes a brief explanation of the two sound
measurements (sound pressure level (SPL) and sound exposure level
(SEL)) frequently used in the discussions of acoustic effects in this
document.
SPL
Sound pressure is the sound force per unit area, and is usually
measured in micropascals (mPa), where 1 Pa is the pressure resulting
from a force of one newton exerted over an area of one square meter.
The sound levels to which most mammals are sensitive extend over
many orders of magnitude and, for this reason, it is convenient to use
a logarithmic scale (the decibel (dB) scale) when measuring sound. SPL
is expressed as the ratio of a measured sound pressure and a reference
level. The commonly used reference pressure level in underwater
acoustics is 1 mPa, and the units for SPLs are dB re: 1 mPa.
SPL (in dB) = 20 log (pressure / reference pressure)
SPL is an instantaneous measurement and can be expressed as the
peak, the peak-peak, or the root mean square (rms). Root mean square,
which is the square root of the arithmetic average of the squared
instantaneous pressure values, is typically used in discussions of the
effects of sounds on vertebrates. SPL does not take the duration of a
sound into account.
SEL
In this proposed authorization, effect thresholds are expressed in
terms of sound exposure level SEL. SEL is an energy metric that
integrates the squared instantaneous sound pressure over a stated time
interval. The units for SEL are dB re: 1 mPa2-s.
SEL = SPL + 10log(duration)
As applied to tactical sonar, the SEL includes both the ping SPL
and the duration. Longer-duration pings and/or higher-SPL pings will
have a higher SEL.
If an animal is exposed to multiple pings, the SEL in each
individual ping is summed to calculate the total SEL. Since mammalian
threshold shift (TS) data show less effect from intermittent exposures
compared to continuous exposures with the same energy (Ward, 1997),
basing the effect thresholds on the total received SEL may be a
conservative approach for treating multiple pings; as some recovery may
occur between pings and lessen the effect of a particular exposure.
The total SEL depends on the SPL, duration, and number of pings
received. The acoustic effects on hearing that result in temporary
threshold shift (TTS) and permanent threshold shift (PTS), do not imply
any specific SPL, duration, or number of pings. The SPL and duration of
each received ping are used to calculate the total SEL and determine
whether the received SEL meets or exceeds the effect thresholds. For
example, the sub-TTS behavioral effects threshold of 173 dB SEL would
be reached through any of the following exposures:
A single ping with SPL = 173 dB re 1 mPa and duration = 1 second.
A single ping with SPL = 170 dB re 1 mPa and duration = 2 seconds.
Two pings with SPL = 170 dB re 1 mPa and duration = 1 second.
Two pings with SPL = 167 dB re 1 mPa and duration = 2 seconds.
Potential Physiological Effects
Physiological function is any of a collection of processes ranging
from biochemical reactions to mechanical interaction and operation of
organs and tissues within an animal. A physiological effect may range
from the most significant of impacts (i.e., mortality and serious
injury) to lesser effects that would define the lower end of the
physiological impact range, such as non-injurious short-term impacts to
auditory tissues.
Exposure to some types of noise may cause a variety of
physiological effects in mammals. For example, exposure to very high
sound levels may affect the function of the visual system, vestibular
system, and internal organs (Ward, 1997). Exposure to high-intensity
sounds of sufficient duration may cause injury to the lungs and
intestines (e.g., Dalecki et al., 2002). Sudden, intense sounds may
elicit a ``startle'' response and may be followed by an orienting
reflex (Ward, 1997; Jansen, 1998). The primary physiological effects of
sound, however, are on the auditory system (Ward, 1997).
Hearing Threshold Shift
In mammals, high-intensity sound may rupture the eardrum, damage
the small bones in the middle ear, or over-stimulate the
electromechanical hair cells that convert the fluid motions caused by
sound into neural impulses that are sent to the brain. Lower level
exposures may cause hearing loss, which is called a threshold shift
(TS) (Miller, 1974). Incidence of TS may be either permanent, in which
case it is called a permanent threshold shift (PTS), or temporary, in
which case it is called a temporary threshold shift (TTS). PTS consists
of non-recoverable physical damage to the sound receptors in the ear,
which can include total or partial deafness, or an impaired ability to
hear sounds in specific frequency ranges. TTS is recoverable and is
considered to result from temporary, non-injurious impacts to hearing-
related tissues. Hearing loss may affect an animal's ability to react
normally to the sounds around it.
The amplitude, duration, frequency, and temporal pattern of sound
exposure all affect the amount of associated TS. As amplitude and
duration of sound exposure increase, so, generally, does the amount of
TS. For continuous sounds, exposures of equal energy will lead to
approximately equal effects (Ward, 1997). For intermittent sounds, less
TS will occur than from a continuous exposure with the same energy
(some recovery will occur between exposures) (Kryter et al., 1966;
Ward, 1997). Additionally, though TTS is temporary, very prolonged
exposure to sound strong enough to elicit TTS, or
[[Page 20991]]
shorter-term exposure to sound levels well above the TTS threshold, can
cause PTS, at least in terrestrial mammals (Kryter, 1985).
Additional detailed information regarding threshold shifts may be
viewed in the Navy's RIMPAC application and in the USWTR DEIS.
Acoustically Mediated Bubble Growth
One theoretical cause of injury to marine mammals is rectified
diffusion (Crum and Mao, 1996), the process of increasing the size of a
bubble by exposing it to a sound field. This process could be
facilitated if the environment in which the ensonified bubbles exist is
supersaturated with gas. Repetitive diving by marine mammals can cause
the blood and some tissues to accumulate gas to a greater degree than
is supported by the surrounding environmental pressure (Ridgway and
Howard, 1979). The deeper and longer dives of some marine mammals (for
example, beaked whales) are theoretically predicted to induce greater
supersaturation (Houser et al., 2001b). If rectified diffusion were
possible in marine mammals exposed to high-level sound, conditions of
tissue supersaturation could theoretically speed the rate and increase
the size of bubble growth. Subsequent effects due to tissue trauma and
emboli would presumably mirror those observed in humans suffering from
decompression sickness.
It is unlikely that the short duration of sonar pings would be long
enough to drive bubble growth to any substantial size, if such a
phenomenon occurs. However, an alternative but related hypothesis has
also been suggested: stable bubbles could be destabilized by high-level
sound exposures such that bubble growth then occurs through static
diffusion of gas out of the tissues. In such a scenario the marine
mammal would need to be in a gas-supersaturated state for a long enough
period of time for bubbles to become of a problematic size. Yet another
hypothesis has speculated that rapid ascent to the surface following
exposure to a startling sound might produce tissue gas saturation
sufficient for the evolution of nitrogen bubbles (Jepson et al., 2003).
In this scenario, the rate of ascent would need to be sufficiently
rapid to compromise behavioral or physiological protections against
nitrogen bubble formation. Collectively, these hypotheses can be
referred to as ``hypotheses of acoustically mediated bubble growth.''
Although theoretical predictions suggest the possibility for
acoustically mediated bubble growth, there is considerable disagreement
among scientists as to its likelihood (Piantadosi and Thalmann, 2004;
Evans and Miller, 2003). To date, Energy Levels (ELs) predicted to
cause in vivo bubble formation within diving cetaceans have not been
evaluated (NOAA, 2002b). Further, although it has been argued that
traumas from some recent beaked whale strandings are consistent with
gas emboli and bubble-induced tissue separations (Jepson et al., 2003),
there is no conclusive evidence of this. Because evidence supporting
the potential for acoustically mediated bubble growth is debatable,
this proposed IHA does not give it any special treatment. Additionally,
the required mitigation measures, which are designed to avoid
behavioral disruptions that could result in abnormal vertical movement
by whales through the water column, should also reduce the potential
for creating circumstances that theoretically contribute to harmful
bubble growth.
Additional information on the physiological effects of sound on
marine mammals may be found in the Navy's IHA application and
associated Environmental Assessment, the USWTR DEIS, and on the Ocean
Acoustic Program section of the NMFS website (see ADDRESSES).
Stress Responses
In addition to PTS and TTS, exposure to mid-frequency sonar is
likely to result in other physiological changes that have other
consequences for the health and ecological fitness of marine mammals.
There is mounting evidence that wild animals respond to human
disturbance in the same way that they respond to predators (Beale and
Monaghan, 2004; Frid, 2003; Frid and Dill, 2002; Gill et al., 2000;
Gill and Sutherland, 2001; Harrington and Veitch, 1992; Lima, 1998;
Romero, 2004). These responses manifest themselves as interruptions of
essential behavioral or physiological events, alteration of an animal's
time or energy budget, or stress responses in which an animal perceives
human activity as a potential threat and undergoes physiological
changes to prepare for a flight or fight response or more serious
physiological changes with chronic exposure to stressors (Frid and
Dill, 2002; Romero, 2004; Sapolsky et al., 2000; Walker et al., 2005).
Classic stress responses begin when an animal's central nervous
system perceives a potential threat to its homeostasis. That perception
triggers stress responses regardless of whether a stimulus actually
threatens the animal; the mere perception of a threat is sufficient to
trigger a stress response (Sapolsky et al., 2005; Seyle, 1950). Once an
animal's central nervous system perceives a threat, it develops a
biological response or defense that consists of a combination of the
four general biological defense responses: behavioral responses,
autonomic nervous system responses, neuroendocrine responses, or immune
response.
The physiological mechanisms behind stress responses involving the
hypothalamus-pituitary-adrenal glands have been well-established
through controlled experiment in the laboratory and natural settings
(Korte et al. 2005; McEwen and Seeman, 2000; Moberg, 1985; 2000;
Sapolsky et al., 2005). Relationships between these physiological
processes, animal behavior, neuroendocrine responses, immune responses,
inhibition of reproduction (by suppression of pre-ovulatory luteinizing
hormones), and the costs of stress responses have also been documented
through controlled experiment in both laboratory and free-living
animals (for examples see, Holberton et al., 1996; Hood et al., 1998;
Jessop et al., 2003; Krausman et al., 2004; Lankford et al., 2005;
Reneerkens et al., 2002; Thompson and Hamer, 2000; Tilbrook et al.,
2000).
The available evidence suggests that: with the exception of
unrelieved pain or extreme environmental conditions, in most animals
(including humans) chronic stress results from exposure to a series of
acute stressors whose cumulative biotic costs produce a pathological or
pre-pathological state in an animal. The biotic costs can result from
exposure to an acute stressor or from the accumulation of a series of
different stressors acting in concert before the animal has a chance to
recover.
Although these responses have not been explicitly identified in
marine mammals, they have been identified in other vertebrate animals
and every vertebrate mammal that has been studied, including humans.
Because of the physiological similarities between marine mammals and
other mammal species, NMFS believes that acoustic energy sufficient to
trigger onset PTS or TTS is likely to initiate physiological stress
responses. More importantly, NMFS believes that marine mammals might
experience stress responses at received levels lower than those
necessary to trigger onset TTS.
Potential Behavioral Effects
For a military readiness activity, Level B Harassment is defined as
``any act that disturbs or is likely to disturb a marine mammal or
marine mammal stock in the wild by causing disruption of natural
[[Page 20992]]
behavioral patterns, including, but not limited to, migration,
surfacing, nursing, breeding, feeding, or sheltering, to a point where
such behavioral patterns are abandoned or significantly altered.''
As discussed above, TTS consists of temporary, short-term impacts
to auditory tissue that alter physiological function, but that are
fully recoverable without the requirement for tissue replacement or
regeneration. An animal that experiences a temporary reduction in
hearing sensitivity suffers no permanent injury to its auditory system,
but, for an initial time post-exposure, may not perceive some sounds
due to the reduction in sensitivity. As a result, the animal may not
respond to sounds that would normally produce a behavioral reaction
(such as a predator or the social calls of conspecifics, which play
important roles in mother-calf relations, reproduction, foraging, and
warning of danger). This lack of response qualifies as a temporary
disruption of normal behavioral patterns - the animal is impeded from
responding in a normal manner to an acoustic stimulus.
NMFS also considers disruption of the behavior of marine mammals
that can result from sound levels lower than those considered necessary
for TTS to occur (often referred to as sub-TTS behavioral disruption).
Though few studies have specifically documented the effects of tactical
mid-frequency sonar on the behavior of marine mammals in the wild, many
studies have reported the effects of a wide range of intense
anthropogenic acoustic stimuli on specific facets of marine mammal
behavior, including migration (Malme et al., 1984; Ljungblad et al.,
1988; Richardson et al., 1999), feeding (Malme et al., 1988), and
surfacing (Nowachek et al., 2004). Below, NMFS summarizes the results
of two studies and one after-the-fact investigation wherein the natural
behavior patterns of marine mammals exposed to levels of tactical mid-
frequency sonar, or sounds similar to mid-frequency sonar, lower than
those thought to induce TTS were disrupted to the point where it was
abandoned or significantly altered:
(1) Finneran and Schlundt (2004) analyzed behavioral observations
from related TTS studies (Schlundt et al., 2000; Finneran et al., 2001;
2003) to calculate cetacean behavioral reactions as a function of known
noise exposure. During the TTS experiments, 4 dolphins and 2 white
whales were exposed during a total of 224 sessions to 1-s pulses
between 160 and 204 dB re 1 microPa (root-mean-square sound pressure
level (SPL)), at 0.4, 3, 10, 20, and 75 kHz. Finneran and Schlundt
(2004) evaluated the behavioral observations in each session and
determined whether a ``behavioral alteration'' (ranging from
modifications of response behavior during hearing sessions to attacking
the experimental equipment) occurred. For each frequency, the
percentage of sessions in which behavioral alterations occurred was
calculated as a function of received noise SPL. By pooling data across
individuals and test frequencies, respective SPL levels coincident with
responses by 25, 50, and 75 percent behavioral alteration were
documented. 190 dB re 1 microPa (SPL) is the point at which 50 percent
of the animals exposed to 3, 10, and 20 kHz tones were deemed to
respond with some behavioral alteration, and the threshold that the
Navy originally proposed for sub-TTS behavioral disturbance.
(2) Nowacek et al. (2004) conducted controlled exposure experiments
on North Atlantic right whales using ship noise, social sounds of con-
specifics, and an alerting stimulus (frequency modulated tonal signals
between 500 Hz and 4.5 kHz). Animals were tagged with acoustic sensors
(D-tags) that simultaneously measured movement in three dimensions.
Whales reacted strongly to alert signals at received levels of 133-148
dB SPL, mildly to conspecific signals, and not at all to ship sounds or
actual vessels. The alert stimulus caused whales to immediately cease
foraging behavior and swim rapidly to the surface. Although SEL values
were not directly reported, based on received exposure durations,
approximate received values were on the order of 160 dB re: 1
microPa\2\-s.
(3) NMFS (2005) evaluated the acoustic exposures and coincident
behavioral reactions of killer whales in the presence of tactical mid-
frequency sonar. In this case, none of the animals were directly fitted
with acoustic dosimeters. However, based on a Naval Research Laboratory
(NRL) analysis that took advantage of the fact that calibrated
measurements of the sonar signals were made in situ and using advanced
modeling to bound likely received exposures, estimates of received
sonar signals by the killer whales were possible. Received SPL values
ranged from 121 to 175 dB re: 1 microPa. The most probable SEL values
were 169.1 to 187.4 dB re: 1 microPa\2\-s; worst-case estimates ranged
from 177.7 to 195.8 dB re: 1 microPa\2\-s. Researchers observing the
animals during the course of sonar exposure reported unusual
alterations in swimming, breathing, and diving behavior.
For more detailed information regarding how marine mammals may
respond to sound, see the Navy's IHA application, the Navy's associated
EA, Richardson's Marine Mammals and Noise (1995), or the references
cited on NMFS' Ocean Acoustic Program website (see ADDRESSES)
Proposed Harassment Thresholds
For the purposes of the proposed IHA for this activity, NMFS
recognizes three levels of take; Level A Harassment (Injury), Level B
Harasssment (Behavioral Disruption), and mortality (or serious injury
that may lead to mortality) (Table 2). Mortality, or serious injury
leading to mortality, may not be authorized with an IHA.
NMFS has determined that for acoustic effects, acoustic thresholds
are the most effective way to consistently both apply measures to avoid
or minimize the impacts of an action and to quantitatively estimate the
effects of an action. Thresholds are commonly used in two ways: (1) To
establish a shut-down or power down zone, i.e., if an animal enters an
area calculated to be ensonified above the level of an established
threshold, a sound source is powered down or shut down; and (2) to
calculate take, for example, if the Level A Harassment threshold is 215
dB, a model may be used to calculate the area around the sound source
that will be ensonified to that level or above, then, based on the
estimated density of animals and the distance that the sound source
moves, NMFS can estimate the number of marine mammals exposed to 215
dB. The rationale behind the acoustic thresholds proposed for this
authorization are discussed below.
[[Page 20993]]
----------------------------------------------------------------------------------------------------------------
Levels of Take Pursuant to the MMPA Basis of Threshold Proposed Threshold
----------------------------------------------------------------------------------------------------------------
Level A harassment (Injury) Permanent Threshold Shift 215 dB (SEL)
(PTS)
Level B Harassment (Behavioral Effects) Temporary Threshold Shift 195 dB
(PTS)
Sub-TTS Behavioral Effects 173 dB (SEL)
Mortality, or Serious Injury That May Lead to Not enough information for May not be authorized with an
Mortality (Stranding) quantitative threshold IHA
----------------------------------------------------------------------------------------------------------------
Table 2. The three levels of take addressed in the MMPA, how NMFS measures them in regard to acoustic effects,
and the propsed thresholds for this authorization.
TTS
Because it is non-injurious, NMFS considers TTS as Level B
harassment (behavioral disruption) that is mediated by physiological
effects on the auditory system. The smallest measurable amount of TTS
(onset-TTS) is taken as the best indicator for slight temporary sensory
impairment. However, as mentioned earlier, NMFS believes that
behavioral disruptions may result from received levels of tactical
sonar lower than those thought to induce TTS and, therefore, NMFS does
not consider on-set TTS to be the lowest level at which Level B
Harassment may occur. NMFS considers the threshold for Level B
Harasment as the received levels from which sub-TTS behavioral
disruptions are likely to result (discussed in Sub-TTS sub-section).
However, the threshold for Level A Harassment (PTS) is derived from the
threshold for TTS and, therefore, it is necessary to describe how the
TTS threshold was developed.
The proposed TTS threshold is primarily based on the cetacean TTS
data from Schlundt et al. (2000). These tests used short-duration tones
similar to sonar pings, and they are the most directly relevant data
for the establishing TTS criteria. The mean exposure EL required to
produce onset-TTS in these tests was 195 dB re 1 microPa\2\-s. This
result is corroborated by the short-duration tone data of Finneran et
al. (2000, 2003) and the long-duration noise data from Nachtigall et
al. (2003a,b). Together, these data demonstrate that TTS in cetaceans
is correlated with the received EL and that onset-TTS exposures are fit
well by an equal-energy line passing through 195 dB re 1 microPa\2\-s.
The justification for establishing the 195 dB acoustic criteria for
TTS is described in detail in both the Navy's RIMPAC IHA application
and the USWTR DEIS (see ADDRESSES).
PTS
PTS consists of non-recoverable physical damage to the sound
receptors in the ear and is, therefore, classified as Level A
harassment under the MMPA. For acoustic effects, because the tissues of
the ear appear to be the most susceptible to the physiological effects
of sound, and because threshold shifts (TSs) tend to occur at lower
exposures than other more serious auditory effects, NMFS has determined
that permanent threshold shift (PTS) is the best indicator for the
smallest degree of injury that can be measured. Therefore, the acoustic
exposure associated with onset-PTS is used to define the lower limit of
the Level A harassment.
PTS data do not currently exist for marine mammals and are unlikely
to be obtained due to ethical concerns. However, PTS levels for these
animals may be estimated using TTS data and relationships between TTS
and PTS. NMFS proposes the use of 215 dB re 1 mPa\2\-s as the acoustic
threshold for PTS. This threshold is based on a 20 dB increase in
exposure EL over that required for onset-TTS (195 dB). Extrapolations
from terrestrial mammal data indicate that PTS occurs at 40 dB or more
of TS, and that TS growth occurs at a rate of approximately 1.6 dB TS
per dB increase in EL. There is a 34 dB TS difference between onset-TTS
(6 dB) and onset-PTS (40 dB). Therefore, an animal would require
approximately 20dB of additional exposure (34 dB divided by 1.6 dB)
above onset-TTS to reach PTS.
The justification for establishing the 215 dB acoustic criteria for
PTS is described in detail in both the Navy's RIMPAC IHA application
and the Undersea Warfare Training Range USWTR DEIS (see ADDRESSES).
Sub-TTS Behavioral Disruption
NMFS believes that behavioral disruption of marine mammals may
result from received levels of mid-frequency sonar lower than those
believed necessary to induce TTS, and further, that the lower limit of
Level B Harassment may be defined by the received sound levels
associated with these sub-TTS behavioral disruptions. As of yet, no
controlled exposure experiments have been conducted wherein wild
cetaceans are deliberately exposed to tactical mid-frequency sonar and
their reactions carefully observed. However, NMFS believes that in the
absence of controlled exposure experiments, the following
investigations and reports (described previously in the Behavioral
Effects section) constitute the best available scientific information
for establishing an appropriate acoustic threshold for sub-TTS
behavioral disruption: (1) Finneran and Schlundt (2004), in which
behavioral observations from TTS studies of captive bottlenose dophins
and beluga whales are analyzed as a function of known noise exposure;
(2) Nowachek et al. (2004), in which controlled exposure experiments
were conducted on North Atlantic right whales using ship noise, social
sounds of con-specifics, and an alerting stimulus; and (3) NMFS (2005),
in which the behavioral reactions of killer whales in the presence of
tactical mid-frequency sonar were observed, and analyzed after the
fact. Based on these three studies, NMFS has set the sub-TTS behavioral
disruption threshold at 173 dB re 1 mPa\2\-s (SEL).
The Finneran and Schlundt (2004) analysis is an important piece in
the development of an appropriate acoustic threshold for sub-TTS
behavioral disruption because: (1) researchers had superior control
over and ability to quantify noise exposure conditions; (2) behavioral
patterns of exposed marine mammals were readily observable and
definable; and, (3) fatiguing noise consisted of tonal noise exposures
with frequencies contained in the tactical mid-frequency sonar
bandwidth. In Finneran and Schlundt (2004) 190 dB re 1 mPa (SPL) is the
point at which 50 percent of the animals exposed to 3, 10, and 20 kHz
tones were deemed to respond with some behavioral alteration. This 50
percent behavior alteration level (190 dB SPL) may be converted to an
SEL criterion of 190 dB re 1 mPa\2\-s (the numerical values are
identical because exposure durations were 1-s), which provides
consistency with the Level A (PTS) effects threshold, which are also
expressed in SEL. The Navy proposed 190 dB (SEL) as the acoustic
threshold for sub-TTS
[[Page 20994]]
behavioral disruption in the first IHA application they submitted to
NMFS.
NMFS acknowledges the advantages arising from the use of behavioral
observations in controlled laboratory conditions; however, there is
considerable uncertainty regarding the validity of applying data
collected from trained captives conditioned to not respond to noise
exposure in establishing thresholds for behavioral reactions of naive
wild individuals to a sound source that apparently evokes strong
reactions in some marine mammals. Although wide-ranging in terms of
sound sources, context, and type/extent of observations reported, the
large and growing body of literature regarding behavioral reactions of
wild, naive marine mammals to anthropogenic exposure generally suggests
that wild animals are behaviorally affected at significantly lower
levels than those determined for captive animals by Finneran and
Schlundt (2004). For instance, some cetaceans exposed to human noise
sound sources, such as seismic airgun sounds and low frequency sonar
signals, have been shown to exhibit avoidance behavior when the animals
are exposed to noise levels of 140-160 dB re: 1 mPa under certain
conditions (Malme et al., 1983; 1984; 1988; Ljungblad et al., 1988;
Tyack and Clark, 1998). Richardson et al. (1995) reviewed the
behavioral response data for many marine mammal species and a wide
range of human sound sources.
Two specific situations for which exposure conditions and
behavioral reactions of free-ranging marine mammals exposed to sounds
very similar to those proposed for use in RIMPAC are considered by
Nowacek et al. (2004) and NMFS (2005) (described previously in
Behavioral Effects subsection). In the Nowacek et al. (2004) study,
North Atlantic right whales reacted strongly to alert signals at
received levels of 133-148 dB SPL, which, based on received exposure
durations, is approximately equivalent to 160 dB re: 1 mPa2-s (SEL). In
the NMFS (2005) report, unusual alterations in swimming, breathing, and
diving behaviors of killer whales observed by researchers in Haro
Strait were correlated, after the fact, with the presence of estimated
received sound levels between 169.1and 187.4 dB re: 1 mPa\2\-s (SEL).
While acknowledging the limitations of all three of these studies
and noting that they may not necessarily be predictive of how wild
cetaceans might react to mid-frequency sonar signals in the OpArea,
NMFS believes that these three studies are the best available science
to support the selection of an acoustic sub-TTS behavioral disturbance
threshold at this time. Taking into account all three studies, NMFS has
established 173 dB re: 1 mPa\2\ (SEL) as the threshold for sub-TTS
behavioral disturbance.
Stranding and Mortality
Over the past 10 years, there have been four stranding events
coincident with military mid-frequency sonar use that are believed to
most likely have been caused by exposure to the sonar. These occurred
in Greece (1996), the Bahamas (2000), Madeira (2000) and Canary Islands
(2002). A number of other stranding events coincident to the operation
of mid-frequency sonar and resulting in the death of beaked whales or
other species (minke whales, dwarf sperm whales, pilot whales) have
been reported, though the majority have not been investigated to the
level of the Bahamas stranding and, therefore, other causes cannot be
ruled out. One of these strandings occurred in Hanalei Bay during the
last RIMPAC exercise in 2004.
Greece, Madeira, and Canary Islands
Twelve Cuvier's beaked whales stranded along the western coast of
Greece in 1996. The test of a low- and mid-frequency active sonar
system conducted by NATO was correlated with the strandings by an
analysis published in Nature. A subsequent NATO investigation found the
strandings to be closely related, in time, to the movements of the
sonar vessel, and ruled out other physical factors as a cause.
In 2000, four beaked whales stranded in Madeira while several NATO
ships were conducting an exercise near shore. Scientists investigating
the stranding found that the injuries, which included blood in and
around the eyes, kidney lesions, and pleural hemorrhage, as well as the
pattern of the stranding suggested that a similar pressure event
precipitated or contributed to strandings in both Madeira and Bahamas
(see Bahamas sub-section).
In 2002, at least 14 beaked whales of three different species
stranded in the Canary Islands while a naval exercise including Spanish
vessels, U.S. vessels, and at least one vessel equipped with mid-
frequency sonar was conducted in the vicinity. Four more beaked whales
stranded over the next several days. The subsequent investigation,
which was reported in both Nature and Veterinary Pathology, revealed a
variety of traumas, including emboli and lesions suggestive of
decompression sickness.
Bahamas
NMFS and the Navy prepared a joint report addressing the multi-
species stranding in the Bahamas in 2000, which took place within 24
hours of U.S. Navy ships using active mid-frequency sonar as they
passed through the Northeast and Northwest Providence Channels. Of the
17 cetaceans that stranded (Cuvier's beaked whales, Blainsville's
beaked whales, Minke whales, and a spotted dolphin), seven animals died
on the beach (5 Cuvier's beaked whales, 1 Blainsville's beaked whale,
and the spotted dolphin) and the other 10 were returned to the water
alive (though their fate is unknown). A comprehensive investigation was
conducted and all possible causes of the stranding event were
considered, whether they seemed likely at the outset or not. The only
possible contributory cause to the strandings and cause of the lesions
that could not be ruled out was intense acoustic signals (the dolphin
necropsy revealed a disease and the death is considered unrelated to
the others).
Based on the way in which the strandings coincided with ongoing
naval activity involving tactical mid-frequency sonar use, in terms of
both time and geography, the nature of the physiological effects
experienced by the dead animals, and the absence of any other acoustic
sources, the investigation team concluded that mid-frequency sonars
aboard U.S. Navy ships that were in use during the sonar exercise in
question were the most plausible source of this acoustic or impulse
trauma. This sound source was active in a complex environment that
included the presence of a surface duct, unusual and steep bathymentry,
a constricted channel with limited egress, intensive use of multiple,
active sonar units over an extended period of time, and the presence of
beaked whales that appear to be sensitive to the frequencies produced
by these sonars. The investigation team concluded that the cause of
this stranding event was the confluence of the Navy mid-frequency sonar
and these contributory factors working together, and further
recommended that the Navy avoid operating mid-frequency sonar in
situations where these five factors would be likely to occur. This
report does not conclude that all five of these factors must be present
for a stranding to occur, nor that beaked whales are the only species
that could potentially be affected by the confluence of the other
factors. Based on this, NMFS believes that the presence of surface
ducts, steep bathymetry, and/or constricted channels added to the
operation of mid-frequency
[[Page 20995]]
sonar in the presence of cetaceans (especially beaked whales and,
potentially, deep divers) may increase the likelihood of producing a
sound field with the potential to cause cetaceans to strand, and
therefore, necessitates caution.
Hanalei Bay
Approximately 150-200 melon-headed whales (Peponocephala electra -
a deep water species) live stranded (i.e. the animals entered and
remained in unusual habitat) in Hanalei Bay on the morning of July 3,
2004 at approximately 7 a.m. RIMPAC exercises involving mid-frequency
sonar were conducted on July 3, but the official exercise did not
commence until approximately 8 a.m. and, thus, could not have been the
original triggering event. However, as six naval surface vessels
traveled to the operational area the previous day, each intermittently
transmitted active sonar during ``coordinated submarine training
exercises'' as they approached Kauai from the south. NMFS conducted a
detailed sound propagation analysis of the sonar transmissions of
Japanese and U.S. naval vessels transiting from Pearl Harbor to Kauai
on the afternoon and evening of 2 July 2004. Predicted sound fields
were calculated for five positions along the known tracks. For each
ship position where active sonar was used, transit speeds from areas to
the south and east of Kauai necessary to reach Hanalei Bay by 7a.m.
were determined. These transit rates were then compared with the ship
locations and predicted sound fields. Results indicate that animals
exposed to military sonar signals near the vessels could have reached
the Bay while swimming at rates believed sustainable over relatively
long periods for this species.
The analysis is by no means conclusive evidence that exposure to
tactical sonar on 2 July resulted in the pod of whales stranding in
Hanalei Bay on July 3. However, based on these results, NMFS concludes
that it was possible that sonar transmissions caused behavioral
responses in the animals that led to their swimming away from the sound
source, into the sound shadow of the island of Kauai, and entering
Hanalei Bay (a shallower environment than they usually inhabit).
Further, it is possible that sonar transmissions during the official
RIMPAC exercise on July 3 could have prevented some of whales from
leaving the Bay (witnesses observed whales attempting several times to
depart the Bay, only to return rapidly once just outside it). The Navy
modeled the sound transmissions during the event and calculated that
the received level at Hanalei Bay from the sonar operated at the PMRF
range on July 3 would have been approximately 147.5 dB re 1 mPa.
Beaked Whales
Recent beaked whale strandings have prompted inquiry into the
relationship between mid-frequency active sonar and the cause of those
strandings. Although Navy mid-frequency active tactical sonar has been
identified as the most plausible contributory source to the 2000
Bahamas stranding event, the specific mechanisms that led to that
stranding are not understood, and there is uncertainty regarding the
ordering of effects that led to the stranding. It is uncertain whether
beaked whales were directly injured by sound (a physiological effect)
prior to stranding or whether a behavioral response to sound occurred
that ultimately caused the beaked whales to strand and be injured.
Several potential physiological outcomes caused by behavioral
responses to high-intensity sounds have been suggested by Cox et al.
(in press). These include: gas bubble formation caused by excessively
fast surfacing; remaining at the surface too long when tissues are
supersaturated with nitrogen; or diving prematurely when extended time
at the surface is necessary to eliminate excess nitrogen. Baird et al.
(2005) found that slow ascent rates from deep dives and long periods of
time spent within 50 m of the surface were typical for both Cuvier's
and Blainsville's beaked whales, the two species involved in mass
strandings related to naval sonar. These two behavioral mechanisms may
be necessary to purge excessive dissolved nitrogen concentrated in
their tissues during their frequent long dives (Baird et al., 2005).
Baird et al. (2005) further suggests that abnormally rapid ascents or
premature dives in response to high-intensity sonar could indirectly
result in physical harm to the beaked whales, through the mechanisms
described above (gas bubble formation or non-elimination of excess
nitrogen).
During the RIMPAC exercise there will be use of multiple sonar
units in an area where three beaked whale species may be present. A
surface duct may be present in a limited area for a limited period of
time. Although most of the ASW training events will take place in the
deep ocean, some will occur in areas of high bathymetric relief.
However, none of the training events will take place in a location
having a constricted channel with limited egress similar to the
Bahamas. Consequently, not all five of the environmental factors
believed to contribute to the Bahamas stranding (mid-frequency sonar,
beaked whale presence, surface ducts, steep bathymetry, and constricted
channels with limited egress) will be present during RIMPAC ASW
exercises. However, as mentioned previously, NMFS believes caution
should be used anytime either steep bathymetry, surface ducting
conditions, or a constricted channel is present in addition to the
operation of mid-frequency tactical sonar and the presence of cetaceans
(especially beaked whales).
In order to avoid the potential for mortality or serious injury
leading to mortality (in the form of strandings), NMFS is requiring
additional mitigation and monitoring beyond that proposed in the Navy's
application. However, given the information regarding beaked whale
strandings and the uncertainty regarding the mechanisms for the
strandings, NMFS will treat all predicted behavioral disturbance of
beaked whales as potential non-lethal injury. All predicted Level B
harassment of beaked whales is therefore given consideration as non-
lethal Level A harassment.
Estimated Take by Incidental Harassment
In order to estimate acoustic exposures from the RIMPAC ASW
operations, acoustic sources to be used were examined with regard to
their operational characteristics. Systems with acoustic source levels
below 205 dB re 1 mPa were not included in the analysis given that at
this source level (205 dB re 1 mPa) or below, a 1-second ping would
attenuate below the behavioral disturbance threshold of 173 dB at a
distance of about 100 meters. As additional verification that they did
not need to be considered further, sources at this level were modeled,
using spreadsheet calculations, to determine the marine mammal
exposures estimated to result from their operation. For example, a
sonobuoy's typical use yielded an exposure area that produced 0 marine
mammal exposures based on the maximum animal density. Such a source was
called non-problematic and was not modeled in the sense of running its
parameters through the environmental model Comprehensive Acoustic
System Simulation (CASS), generating an acoustic footprint, etc. The
proposed counter measures source level was less than 205 dB but its
operational modes were such that a simple ``look'' was not applicable,
and a separate study was conducted to ensure it did not need to be
considered further.
In addition, systems with an operating frequency greater than 100
kHz were not
[[Page 20996]]
analyzed in the detailed modeling as these signals attenuate rapidly,
resulting in very short propagation distances. Acoustic countermeasures
were previously examined and found not to be problematic. The AN/AQS 13
(dipping sonar) used by carrier based helicopters was determined in the
Environmental Assessment/Overseas Environmental Assessment of the SH-
60R Helicopter/ALFS Test Program, October 1999, not to be problematic
due to its limited use and very short pulse length (2 to 5 pulses of
3.5 to 700 msec). Since 1999, during the time of the test program,
there have been over 500 hours of operation, with no environmental
effects observed. The Directional Command Activated Sonobuoy System
(DICASS) sonobuoy was determined not to be problematic having a source
level of 201dB re 1 mPa. These acoustic sources, therefore, did not
require further examination in this analysis.
Based on the information above, only hull mounted mid-frequency
active tactical sonar was determined to have the potential to affect
marine mammals protected under the MMPA and ESA during RIMPAC ASW
training events.
Model
An analysis was conducted for RIMPAC 2006, modeling the potential
interaction of hull mounted mid-frequency active tactical sonar with
marine mammals in the OpArea. The model incorporates site-specific
bathymetric data, time-of-year-specific sound speed information, the
sound source's frequency and vertical beam pattern, and multipath
pressure information as a function of range, depth and bearing. Results
were calculated based on the typical ASW activities planned for RIMPAC
2006. Acoustic propagation and mammal population and density data were
analyzed for the July timeframe since RIMPAC occurs in July. The
modeling occurred in five broad steps, listed below.
Step 1. Perform a propagation analysis for the area ensonified
using spherical spreading loss and the Navy's CASS/GRAB program,
respectively.
Step 2. Convert the propagation data into a two-dimensional
acoustic footprint for the acoustic sources engaged in each training
event as they move through the six acoustic exposure model areas.
Step 3. Calculate the total energy flux density level for each
ensonified area summing the accumulated energy of all received pings.
Step 4. Compare the total energy flux density to the thresholds and
determine the area at or above the threshold to arrive at a predicted
marine mammal exposure area.
Step 5. Multiply the exposure areas by the corresponding mammal
population density estimates. Sum the products to produce species sound
exposure rate. Analyze this rate based on the annual number of events
for each exercise scenario to produce annual acoustic exposure
estimates.
The modeled estimate indicates the potential for a total of 33,331
Level B harassment exposures across all marine mammal species.
The results of the model (estimated Level B Harassment takes (Level
A Harassment for beaked whales)) are presented in Table 1. When
analyzing the results of the acoustic exposure modeling to provide an
estimate of effects, it is important to understand that there are
limitations to the ecological data used in the model, and that the
model results must be interpreted within the context of a given
species' ecology and biology.
NMFS believes that the model take estimates are overestimates for
the following reasons:
(1) The implementation of the extensive mitigation and monitoring
that will be required by the IHA (Including large power-down/shut-down
zones, geographic restrictions, and monitors that will almost certainly
sight groups of animals, if not individuals, in time to avoid/minimize
impacts) have not been taken into account.
(2) In the model the Navy used to estimate take, marine mammals
remain stationary as the sound source passes by and their immediate
area is ensonified. NMFS believes that some, if not the majority of
animals, will move away from the sound to some degree, thus receiving a
lower level of energy than estimated by the model.
(3) NMFS interprets the results of the Navy's model as the number
of times marine mammals might be exposed to particular received levels
of sound. However, NMFS believes it would be unrealistic, considering
the fast-paced, multi-vessel nature of the exercise and the fact that
the exercise continues over the course of a month in an area with
resident populations of cetaceans, to assume that each exposure
involves a different whale; some whales are likely to be exposed once,
while others are likely to be exposed more than once.Some elements of
the Navy's modeling, such as its calculation of received levels without
regard to where animals occur in the water column, are conservative.
Other elements, such as its evaluation of some but not all acoustic
sources that would be used during the exercise, may not be
conservative. With regard to RIMPAC 2006, it is NMFS initial view that
an extensive set of mitigation and monitoring requirements like those
set forth in this notice would ensure that impacts on species and
stocks are negligible. This conclusion would not necessarily apply to
other naval acoustic activities whose operational and environmental
parameters may differ. Additional detailed information regarding
potential effects on individual species may be viewed in the Navy's IHA
application (see ADDRESSES).
Potential Effects on Habitat
The primary source of marine mammal habitat impact is acoustic
exposures resulting from ASW activities. However, the exposures do not
constitute a long term physical alteration of the water column or
bottom topography, as the occurrences are of limited duration and are
intermittent in time. Surface vessels associated with the activities
are present in limited duration and are intermittent as well.
Potential Effects on Subsistence Harvest of Marine Mammals
There is no known legal subsistence hunting for marine mammals in
or near the survey area, so the proposed activities will not have any
impact on the availability of the species or stocks for subsistence
users.
Mitigation, Monitoring, and Reporting
The Navy has requested an Incidental Harassment Authorization (IHA)
from NMFS for the take, by harassment, of marine mammals incidental to
RIMPAC ASW exercises in the OpArea. Section 101(a)(5)(D) of the MMPA,
the section pursuant to which IHAs are issued, may not be used to
authorize mortality or serious injury leading to mortality. The Navy's
analysis of the RIMPAC ASW exercises concluded that no mortality or
serious injury leading to mortality would result from the proposed
activities. However, NMFS believes that some marine mammals may react
to mid-frequency sonar, at received levels lower than those thought to
cause direct physical harm, with behaviors that may lead to
physiological harm, stranding, or, potentially, death. Therefore, in
processing the Navy's IHA request, NMFS has required additional
mitigation and monitoring than originally proposed in the Navy's
application to ensure that mortality or serious injury leading to
mortality does not result from the proposed activities.
In any IHA issued there is the requirement to supply the ``means of
[[Page 20997]]
effecting the least practicable [adverse] impact upon the affected
species.'' NMFS' determination of ``the least practicable adverse
impact on the affected species'' includes consideration of personnel
safety, practicality of implementation, and impact on the effectiveness
of military readiness activities. While NMFS' proposed mitigation and
monitoring requirements discussed below are intended to effect the
``least practicable adverse impact'', they are also designed to ensure
that no mortality or serious injury leading to mortality occurs, so
that an IHA may be legally issued under the MMPA.
Standard Operating Procedures Proposed in Navy Application
Navy shipboard lookout(s) are highly qualified and experienced
observers of the marine environment. Their duties require that they
report all objects sighted in the water to the Officer of the Deck
(e.g., trash, a periscope, a marine mammal) and all disturbances (e.g.,
surface disturbance, discoloration) that may be indicative of a threat
to the vessel and its crew. There are personnel serving as lookouts on
station at all times (day and night) when a ship or surfaced submarine
is moving through the water.
Navy lookouts undergo extensive training in order to qualify as a
watchstander. This training includes on-the-job instruction under the
supervision of an experienced watchstander, followed by completion of
the Personal Qualification Standard program, certifying that they have
demonstrated the necessary skills (such as detection and reporting of
partially submerged objects). In addition to these requirements, many
Fleet lookouts periodically undergo a 2-day refresher training course.
The Navy includes marine species awareness as part of its training
for its bridge lookout personnel on ships and submarines. Marine
species awareness training was updated in 2005 and the additional
training materials are now included as required training for Navy
lookouts. This training addresses the lookout's role in environmental
protection, laws governing the protection of marine species, Navy
stewardship commitments, and general observation information to aid in
avoiding interactions with marine species. Marine species awareness and
training is reemphasized by the following means:
Bridge personnel on ships and submarines - Personnel utilize marine
species awareness training techniques as standard operating procedure,
they have available the ``whale wheel'' identification aid when marine
mammals are sighted, and they receive updates to the current marine
species awareness training as appropriate.
Aviation units - All pilots and aircrew personnel, whose airborne
duties during ASW operations include searching for submarine
periscopes, report the presence of marine species in the vicinity of
exercise participants.
Sonar personnel on ships, submarines, and ASW aircraft - Both
passive and active sonar operators on ships, submarines, and aircraft
utilize protective measures relative to their platform.
The Environmental Annex to the RIMPAC Operational Order mandates
specific actions to be taken if a marine mammal is detected and these
actions are standard operating procedure throughout he exercise.
Implementation of these protective measures is a requirement and
involves the chain of command with supervision of the activities and
consequences for failing to follow orders. Activities undertaken on a
Navy vessel or aircraft are highly controlled. Very few actions are
undertaken on a Navy vessel or aircraft without oversight by and
knowledge of the chain of command. Failure to follow the orders of
one's superior in the chain of command can result in disciplinary
action.
Operating Procedures
The following procedures are implemented to maximize the ability of
operators to recognize instances when marine mammals are close aboard
and avoid adverse effects to listed species:
Visual detection/ships and submarines - Ships and surfaced
submarines have personnel on lookout with binoculars at all times when
the vessel is moving through the water. Standard operating procedure
requires these lookouts maintain surveillance of the area visible
around their vessel and to report the sighting of any marine species,
disturbance to the water's surface, or object (unknown or otherwise) to
the Officer in Command.
Visual detection/aircraft - Aircraft participating in RIMPAC ASW
events will conduct and maintain, whenever possible, surveillance for
marine species prior to and during the event. The ability to
effectively perform visual searches by participating aircraft crew will
be heavily dependent upon the primary duties assigned as well as
weather, visibility, and sea conditions. Sightings would be immediately
reported to ships in the vicinity of the event as appropriate.
Passive detection for submarines - Submarine sonar operators will
review detection indicators of close-aboard marine mammals prior to the
commencement of ASW operations involving active mid-frequency sonar.
When marine mammals are detected close aboard, all ships,
submarines, and aircraft engaged in ASW would reduce mid-frequency
active sonar power levels in accordance with the following specific
actions:
(1) Helicopters shall observe/survey the vicinity of an event
location for 10 minutes before deploying active (dipping) sonar in the
water. Helicopters shall not dip their sonar within 200 yards of a
marine mammal and shall secure pinging if a marine mammal closes within
200 yards after pinging has begun.
(2) Note: Safety radii, power-down, and shut-down zones proposed by
the Navy have been replaced with more conservative measures required by
NMFS and are discussed in the next section.
The RIMPAC Operational Order Environmental Annex (Appendix A)
includes these specific measures that are to be followed by all
exercise participants.
The Navy proposes that training be provided to exercise
participants and NOAA officials before and during the in port phase of
RIMPAC (26-30 Jun 06). This will consist of exercise participants (CO/
XO/Ops) reviewing the C3F Marine Mammal Brief, available OPNAV N45
video presentations, and a NOAA brief presented by C3F on marine mammal
issues in the Hawaiian Islands. The Navy will also provide the
following training for RIMPAC participants:
(1)NUWC will train observers on marine mammal identification
observation techniques
(2)Third fleet will brief all participants on marine mammal
mitigation requirements
(3)Participants will receive video training on marine mammal
awareness
(4)Navy offers NOAA/NMFS opportunity to send a rep to the ashore
portion of the exercise to address participants and/or observe
training.
Conservation Measures (Research)
The Navy will continue to fund ongoing marine mammal research in
the Hawaiian Islands. Results of conservation efforts by the Navy in
other locations will also be used to support efforts in the Hawaiian
Islands. The Navy is coordinating long term monitoring/ studies of
marine mammals on various established ranges and operating areas:
(1) Coordinating with NMFS to conduct surveys within the selected
[[Page 20998]]
Hawaiian Islands Operating Area as part of a baseline monitoring
program.
(2) Implementing a long-term monitoring program of marine mammal
populations in the OpArea, including evaluation of trends.
(3) Continuing Navy research and Navy contribution to university/
external research to improve the state of the science regarding marine
species biology and acoustic effects.
(4) Sharing data with NMFS and the public, via the literature, for
research and development efforts.
The Navy has contracted with a consortium of researchers from Duke
University, University of North Carolina at Wilmington, University of
St. Andrews, and the NMFS Northeast Fisheries Science Center to conduct
a pilot study analysis and develop a survey and monitoring plan that
lays out the recommended approach for surveys (aerial/shipboard,
frequency, spatial extent, etc.) and data analysis (standard line-
transect, spatial modeling, etc.) necessary to establish a baseline of
protected species distribution and abundance and monitor for changes
that might be attributed to ASW operations on the Atlantic Fleet
Undersea Warfare Training Range. The Research Design for the project
will be utilized in evaluating the potential for implementing similar
programs in the Hawaiian Islands ASW operations areas. In addition, a
Statement of Interest has been promulgated to initiate a similar
research and monitoring project in the Hawaiian Islands and the
remainder of the Pacific Fleet OPAREAs. The execution of funding to
begin the resultant monitoring is planned for the fall of 2006.
Reporting
The RIMPAC Operational Order Environmental Annex (see example in
Appendix A of the application) includes specific reporting requirements
related to marine mammals.
Additional Proposed Mitigation, Monitoring, and Reporting Measures
Required by NMFS
The following protective mitigation and monitoring measures are
proposed to be implemented in addition to the standard operating
procedures discussed in the previous section:
(1) The Navy will operate sonar at the lowest practicable level,
not to exceed 235 dB, except for occasional short periods of time to
meet tactical training objectives.
(2) Safety Zones - When marine mammals are detected by any means
(aircraft, lookout, or aurally) within 1000 m of the sonar dome (the
bow), the ship or submarine will limit active transmission levels to at
least 6 dB below the equipment's normal operating level for sector
search modes. Within the water depths encompassed by the proposed
RIMPAC areas, a 6-dB reduction in ping levels would reduce the range of
potential acoustic effects to about half of its original distance.
This, in turn, would reduce the area of acoustic effects to about one
quarter of its original size. Ships and submarines would continue to
limit maximum ping levels by this 6-dB factor until the animal has been
seen to leave the area, has not been seen for 30 minutes, or the vessel
has transited more than 2000 m beyond the location of the sighting.
Should the marine mammal be detected within or closing to inside
500 m of the sonar dome, active sonar transmissions will be limited to
at least 10 dB below the equipment's normal operating level for sector
search modes. Ships and submarines would continue to limit maximum ping
levels by this 10-dB factor until the animal has been seen to leave the
area, has not been seen for 30 minutes, or the vessel has transited
more than 1500 m beyond the location of the sighting.
Should the marine mammal be detected within or closing to inside
200 m of the sonar dome, active sonar transmissions will cease. When a
marine mammal or sea turtle is detected closing to inside approximately
200 m of the sonar dome, the principal risk becomes potential physical
injury from collision. Accordingly, ships and submarines shall maneuver
to avoid collision if the marine species closes within 200 m to the
extent possible, with safety of the vessel being paramount. Sonar will
not resume until the animal has been seen to leave the area, has not
been seen for 30 minutes, or the vessel has transited more than 1200 m
beyond the location of the sighting.
(3) In strong surface ducting conditions, the Navy will enlarge the
safety zones such that a 6-dB power-down will occur if a marine mammal
enters the zone within a 2000 m radius around the source, a 10-dB
power-down will occur if an animal enters the 1000 m zone, and shut
down will occur when an animal closes within 500 m of the sound source.
(4) In low visibility conditions (i.e., whenever the entire safety
zone cannot be effectively monitored due to nighttime, high sea state,
or other factors), the Navy will use additional detection measures,
such as infrared (IR) or enhanced passive acoustic detection. If
detection of marine mammals is not possible out to the prescribed
safety zone, the Navy will power down sonar as if marine mammals were
present in the zones they cannot see (for example, at night, if night
goggles allow detection out to 1000 m, power-down would not be
necessary under normal conditions, however, in strong surface duct
conditions, the Navy would need to power down 6 dB, as they could not
effectively detect mammals out to 2000 m, the prescribed safety zone ).
(5) With the exception of three specific choke-point exercises
(special measures outlined in item 8), the Navy will not conduct sonar
activities in constricted channels or canyon-like areas.
(6) With the exception of three specific choke-point exercises
(special measures outlined below), the Navy will not operate mid-
frequency sonar within 25 km of the 200 m isobath.
(7) Navy watchstanders, the individuals responsible for detecting
marine mammals in the Navy's standard operating procedures, will
participate in marine mammal observer training by a NMFS-approved
instructor (NMFS will work with Navy to develop appropriate format,
potentially to be presented to Navy personnel during the port phase of
RIMPAC, June 26-30). Training will focus on identification cues and
behaviors that will assist in the detection of marine mammals and the
recognition of behaviors potentially indicative of injury or stranding.
Training will also include information aiding in the avoidance of
marine mammals and the safe navigation of the vessel, as well as
species identification review (with a focus on beaked whales and other
species likely to strand). At least one individual who has received
this training will be present, and on watch, at all times during
operation of tactical mid-frequency sonar, on each vessel operating
mid-frequency sonar.
(8) The Navy will conduct no more than three choke-point exercises.
These exercises will occur in the Kaulakahi Channel (between Kauai and
Niihau) and the Alenuihaha Channel (between Maui and Hawaii). These
exercises will not be conducted in a constricted channel like was
present in the Bahamas, but will fall outside of the requirements
listed above, i.e., to avoid canyon-like areas and to operate sonar
farther than 25 km from the 200 m isobath. Therefore, NMFS has required
additional mitigation and monitoring measures for these three exercises
designed to avoid the possibility of mortality, or serious injury
leading to mortality, of marine mammals. The additional measures for
these three choke-point exercises below are as follows:
[[Page 20999]]
a. The Navy will provide NMFS (Stranding Coordinator and Protected
Resources, Headquarters) and the Hawaii marine patrol with information
regarding the time and place for the choke-point exercises in advance
of the exercises.
b. The Navy will have at least one dedicated Navy observer that has
received the training mentioned above, on board each ship and
conducting observations during the operation of mid-frequency tactical
sonar during the choke-point exercises. The Navy has also authorized
the presence of two experienced marine mammal observers (non-Navy
personnel) to embark on Navy ships for observation during the exercise.
c. The Navy will coordinate a focused monitoring effort around the
choke-point exercises, to include pre-exercise monitoring (2 hours),
during-exercise monitoring, and post-exercise monitoring (1-2 days).
This monitoring effort will include at least one dedicated aircraft or
one dedicated vessel for realtime monitoring from the pre- through
post-monitoring time period, except at night. The vessel or airplane
may be operated by either dedicated Navy personnel, or non-Navy
scientists contracted by the Navy, who will be in regular communication
with a Tactical Officer with the authority to shut-down, power-down, or
delay the start-up of sonar operations. These monitors will communicate
with this Officer to ensure the safety zones are clear prior to sonar
start-up, to recommend power-down and shut-down during the exercise,
and to extensively search for potentially injured or stranding animals
in the area and down-current of the area post-exercise.
d. The Navy will further contract an experienced cetacean
researchers to conduct systematic aerial reconnaissance surveys and
observations before, during, and after the choke-point exercises with
the intent of closely examining local populations of marine mammals
during the RIMPAC exercise.
e. For the Kaulakahi Channel (between Kauai and Niihau), shoreline
reconnaissance and nearshore observations will be undertaken by a team
located at Kekaha (the approximate mid point of the Channel). One of
these individuals was formerly employed by NOAA as a marine mammal
observer and trained NOAA personnel in marine mammal observation
techniques. Additional observations will be made on a daily basis by
range vessels while enroute from Port Allen to the range at PMRF (a
distance of approximately 16 nmi) and upon their return at the end of
each day's activities. Finally, surveillance of the beach shoreline and
nearshore waters bounding PMRF will occur randomly around the clock a
minimum four times in each 24 hour period.
f. For the Alenuihaha Channel (between Maui and Hawaii), in
addition to aerial reconnaissance as described previously, the Navy
will undertake shoreline reconnaissance and nearshore observations by a
team rotating between Mahukona and Lapakahi before, during, and after
the exercise.
(9) NMFS and the Navy will continue coordination on the
``Communications and Response Protocol for Stranded Marine Mammal
Events During Navy Operations in the Pacific Islands Region'' that is
currently under preparation by NMFS PIRO to facilitate communication
during RIMPAC. The Navy will coordinate with the NMFS Stranding
Coordinator for any unusual marine mammal behavior, including
stranding, beached live or dead cetacean(s), floating marine mammals,
or out-of-habitat/milling live cetaceans that may occur at any time
during or shortly after RIMPAC activities. After RIMPAC, NMFS and the
Navy (CPF) will prepare a coordinated report on the practicality and
effectiveness of the protocol that will be provided to Navy/NMFS
leadership.
(10)The Navy will provide a report to NMFS after the completion of
RIMPAC that includes:
a. An estimate of the number of marine mammals harassed based on
both modeled sound and sightings of marine mammals.
b. An assessment of the effectiveness of the mitigation and
monitoring measures with recommendations of how to improve them.
c. Results of the marine species monitoring during the RIMPAC
exercise.
d. As much unclassified information as the Navy can provide
including, but not limited to, where and when sonar was used (including
sources not considered in take estimates, such as submarine and
aircraft sonars) in relation to any measured received levels (such as
at sonobuoys or on PMRF range), source levels, numbers of sources, and
frequencies, so it can be coordinated with observed cetacean behaviors.
The mitigation and monitoring proposed in this IHA are intended to
function adaptively, and NMFS fully expects to refine them for future
authorizations based on the reporting input from the Navy.
Negligible Impact Determination and Avoidance of Mortality of Marine
Mammals
Negligible impact is defined 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.'' Because NMFS does
not expect any mortality or injury to result from these activities,
NMFS believes the authorized takings, by harassment, can be reasonably
expected to not adversely affect the species or stock through effects
on annual rates of survival. NMFS acknowledges that Level B Harassment
to large enough portions of a species or stock or over a long enough
time could potentially adversely affect survival rates, however, due to
the required mitigation and monitoring during this proposed activity
(which reduce the numbers of animals exposed and the levels they are
exposed to), as well as the duration and nature of the activities, NMFS
does not believe RIMPAC will adversely affect survival.
As discussed earlier (see Stress Responses), some portion of the
animals exposed to SELs greater than 173 dB during the RIMPAC exercises
will undergo a physiological stress response. Relationships between
stress responses and inhibition of reproduction (by suppression of pre-
ovulatory luteinizing hormones, for example) have been well-documented.
However, NMFS believes the manner in which individual animals respond
to different stressors varies across a continuum that is normally
distributed with hyper-sensitive and hypo-sensitive animals being on
the tails of the curve. Therefore, NMFS does not believe that much more
than a small portion of animals exposed to sound levels above 173 dB
would respond in a manner that physiologically inhibits reproduction.
Additionally, suppression of pre-ovulatory luteinizing hormones would
only be of a concern to species whose period of reproductive activity
overlaps in time and space with RIMPAC. NMFS also believes that due to
the enhanced nature of the monitoring required in this authorization,
combined with the shutdown zones, the likelihood of seeing and avoiding
mother/calf pairs or animals engaged in social reproductive behaviors
is high. Consequently, NMFS believes it is unlikely the authorized
takings will adversely affect the species stocks through effects on
annual rates of recruitment.
Table 3 summarizes the reasoning behind NMFS' preliminary
negligible
[[Page 21000]]
impact determination, in terms of how mitigation measures contribute
towards it and what other factors were considered. Several of the
measures addressed have a visual monitoring component, which NMFS
recognizes is most effective in reducing impacts to larger animals and
species that travel in larger groups. However, NMFS has also included
coastal and steep bathymetry restrictions, and extended power-down/
shut-down zones, which will significantly reduce the numbers of animals
taken, regardless of whether they are cryptic or easily seen, and will
effectively avoid the likelihood of mortality, or serious injury, of
marine mammals.
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[[Page 21002]]
As mentioned in Table 3, the number of individuals harassed, in
relation to the abundance of the species or stock, factors into the
negligible impact determination. The raw modeled exposure numbers
produced by the model do not take into account how any of the
mitigation or monitoring measures may reduce the number of exposures.
Though no particular numeric reduction of the estimated take numbers as
a result of the mitigation measures can be justified, they are
qualitatively addressed in Table 3 and NMFS believes the numbers of
animals that may be harassed are significantly lower than the number of
modeled exposures.
Additionally, when further analyzing the effects of these takes on
the affected species and stocks, NMFS believes it would be unrealistic,
considering the fast-paced, multi-vessel nature of the exercise and the
fact that the exercise continues over the course of a month in an area
with resident populations of cetaceans, to assume that each exposure
involves a different whale. Some whales are likely to be exposed once,
while others are likely to be exposed more than once. One way to
numerically address this concept is to assume that the exposure events
would be distributed normally, with the exposures that each affect a
different whale falling within one standard deviation (68.26 percent),
the exposures assumed to affect different whales each twice within 2
standard deviations (27.18 percent), the exposures assumed to affect
different whales each 3 times within 3 standard deviations (4.28
percent), and so on, if the populations are larger. If this
relationship is applied to estimated numbers of exposures produced by
the Navy's model, the calculated number of affected animals is
approximately 16 percent less than the estimated number of exposures
for any given species. NMFS acknowledges the lack of specific sonar/
marine mammal data to support this approach, however, NMFS believes
that this approach will help us more closely approximate the number of
animals potentially taken than an assumption that each sonar ping
affects a different cetacean.
To examine the number of individuals harassed in relation to the
species or stock, NMFS divided the raw modeled exposures for each
species by the estimated abundances to see which species may have
relatively large numbers of individuals potentially taken, compared to
the population size (Table 1). Per this calculation, all but two
species may potentially sustain Level B Harassment of up to a maximum
of 38 percent, or less, of the estimated population. Spinner dolphins
and false killer whales were calculated to potentially have Level B
Harassment of up to 103 percent and 51 percent of the population,
respectively. For the reasons stated above, NMFS believes all of the
actual percentages will be significantly less. Also, for the spinner
dolphins and false killer whales in particular, these percentages are
incorrect (too high) because of the following:
Spinner dolphins - The estimated abundance of 2,805 animals was
derived from one line-transect survey of the Hawaiian Islands EEZ
conducted in 2002. The NMFS stock assessment states that the estimate
may be negatively biased because relatively little survey effort
occurred in the nearshore areas where these dolphins are abundant in
the day light hours when the survey was conducted.
False killer whales - The estimated abundance of false killer
whales is based on 12 aerial surveys conducted within 25 nm of the
shore between 1993 and 1998. The NMFS stock assessment report states
that the study underestimates the number of false killer whales within
the Hawaiian EEZ because areas around the Northwestern Hawaiian Islands
and areas beyond 25 nm were not surveyed, and because the data were
uncorrected for the portion of diving animals missed from the survey
aircraft.
To reiterate, NMFS believes that the actual percentages of the
stocks affected by this activity are significantly lower than those
suggested by the modeled exposures.
NMFS has preliminarily determined that with the full implementation
of the all of the proposed mitigation and monitoring measures
(especially the additional measures required by NMFS), the RIMPAC ASW
exercises are highly unlikely to result in the serious injury or death
of a marine mammal. In the unanticipated event that any cases of marine
mammal injury or mortality are judged by NMFS or Navy to result from
these activities, the Navy will cease operating sonar immediately.
NMFS has further preliminarily determined that, based on the nature
and duration of the proposed activities, and dependent upon the full
implementation of the proposed mitigation and monitoring measures, the
RIMPAC ASW exercises will result in no more than the Level B Harassment
of the species addressed here. The Level B Harassment will consist
primarily of temporary behavioral modifications, in the form of
temporary displacement from feeding or sheltering areas, low-level
physiological stress responses, and, to a lesser extent, TTS. NMFS has
further determined that these takings, by harassment, will result in no
more than a negligible impact to the affected species or stocks. To be
conservative, NMFS and the Navy initially used the approach of treating
beaked whales exposed to sound levels thought to induce Level B
Harassment as if they would receive Level A Harassment. However, due to
the extensive mitigation and monitoring levels, NMFS has preliminarily
determined that beaked whales will not experience Level A Harrassment
as a result of these exercises.
Endangered Species Act (ESA)
There are seven marine mammal species and five sea turtle species
that are listed as endangered under the ESA with confirmed or possible
occurrence in the study area: humpback whale, North Pacific right
whale, sei whale, fin whale, blue whale, sperm whale, and Hawaiian monk
seal, loggerhead sea turtle, the green sea turtle, hawksbill sea
turtle, leatherback sea turtle, and olive ridley sea turtle. Most of
the cetacean species and the Hawaiian monk seal are expected to occur
in the OpArea during the RIMPAC exercises. As mentioned previously,
humpback whales are not believed to be present in the July timeframe.
Because definitive information on sei and fin whales is lacking, their
possible presence during the July timeframe was assumed, although it is
unlikely.
Under section 7 of the ESA, the Navy has begun consultation with
NMFS on the proposed RIMPAC ASW exercises. NMFS will also consult
internally on the issuance of an IHA under section 101(a)(5)(D) of the
MMPA for this activity. Consultation will be concluded prior to a
determination on the issuance of an IHA.
National Environmental Policy Act (NEPA)
In April, 2006, the Navy prepared a revised 2006 Supplement on the
2002 Programmatic Environmental Assessment on RIMPAC. This revised EA
has been posted on the Navy website (see ADDRESSES) concurrently with
the publication of this proposed IHA and public comments have been
solicited. Comments on the EA should be addressed to the Navy as
outlined in their Federal Register notice announcing the EA's
availability for comment. NMFS will review the revised EA and the
public comments received and subsequently either adopt it or prepare
its own NEPA document before making a determination on the issuance of
an IHA.
[[Page 21003]]
Preliminary Conclusions
A determination of negligible impact is required for NMFS to
authorize incidental take of marine mammals. By regulation, an activity
has a ``negligible impact'' on a species or stock when it is determined
that the total taking is not likely to reduce annual rates of adult
survival or recruitment (i.e., offspring survival, birth rates). Based
on each species' life history information, the expected behavioral
patterns of the animals in the RIMPAC locations, the duration of the
activity, the anticipated implementation of the required mitigation and
monitoring measures, and an analysis of the behavioral disturbance
levels in comparison to the overall populations, an analysis of the
potential impacts of the Proposed Action on species recruitment or
survival support the conclusion that proposed RIMPAC ASW training
events would have no more than a negligible impact on the affected
species or stocks. NMFS has also determined that the issuance of the
IHA would not have an unmitigable adverse impact on the availability of
the affected species or stocks for subsistence use. Additionally, NMFS
has set forth in this proposed IHA the permissible methods of taking
and requirements pertaining to the mitigation, monitoring and reporting
of such takings.
Proposed Authorization
NMFS proposes to issue an IHA to the Navy for conducting ASW
exercises, using tactical mid-frequency sonar in the OpArea, provided
the previously mentioned mitigation, monitoring, and reporting
requirements are incorporated. NMFS has preliminarily determined that
the proposed activity would result in only the harassment of marine
mammals; would have no more than a negligible impact on the affected
marine mammal stocks; and would not have an unmitigable adverse impact
on the availability of species or stocks for subsistence uses.
Dated: April 18, 2006.
James H. Lecky,
Director, Office of Protected Resources, National Marine Fisheries
Service.
[FR Doc. 06-3831 Filed 4-21-06; 8:45 am]
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