–At 0945hrs PDT a recreational vessel with a man and a woman on board entered from the NE near North Rock at high speed and approached Great Race where they slowed down to transit the Reserve.
–DND has been blasting since 0900hrs this morning.
–A Pearson alumni arrived today to help with some projects over the next few days.
There was 1 visitor to the island today.
Blasting occurred at DND Rocky Point today. Numerous blasts were heard throughout the day including several spaced at intervals less than 10 minutes apart. Some sets of detonations also occurred in series of three. This activity does not conform to the guidelines laid out on the RR website.
(Posted by Adam)
14 Harlequin Ducks have arrived at Race Rocks and are making good use of the fine weather this past week. Unfortunately, these shy birds have been scared away today by bomb blasts on Bentinck Island. Blasting by CFAD Rocky Point has been continuous today with the exception of a lunch break at noon. It is very disappointing that the 5-minute interval designed to minimize DND impact on the ecological reserve has not been observed. Most blasts come in clusters with ~2-minute intervals. The blasting occurring around the time of this report ~13:54 had ~1-minute intervals.
DND BLASTING ACTIVITIES AT ROCKY POINT:
Bentinck island is used by the Department of National Defense as both a demolition range and a testing range for explosives. On the South end of Rocky Point there is a disposal pit where other demolition occurs, and in Whirl Bay, behind Christopher Point, there is an underwater test site. The size of the explosions is supposed to be monitored and controlled , however, we invariable get widely varying impacts. Our ecoguardians have made observations of the impact on sea
From the “burn pit” on Rocky Point
lions, seals and seabirds over the last few years. Invariably the blasting results in the sea lions being scared from the islands . Sometimes they do come back to haul out on the rocks but they often move on to another location. Unfortunately the location of Race Rocks next to these areas makes it very difficult to mitigate the impact of these explosions.
Department of National Defence demolition exercises on Bentinck Island on the behaviour of birds and marine mammals at Race Rocks MPA. In previous years we have observed considerable disruption by military exercises involving blasting on nearby Bentinck Island in the fall just after the sea lions have returned to the island. We have requested that blasts be spread out over a longer period of time during an exercise. Traditionally blasts have come in a series of three. The first one would alert the sea lions, the second would send a few in the water and the third would clear the islands. This year on this one occasion, only two blasts were held at five minutes apart. The results are shown in the video.
from Lester Pearson College who were out for a project week were able to catch the images of the impact of these blasts on the first day from the science centre window and on the second day from the top of the light tower. In the tower, they interviewed Mike Demarchi of LGL who is currently doing a $50,000 contract for the Department of National Defence to monitor the impact of these blasts and to compare them with other disturbances at Race Rocks.Update 2020: and its still going on —-https://www.racerocks.ca/tag/blasting/
and on January 27-2020: another set of blasts from Bentinck Island clears the docks of sealions:
https://www.racerocks.ca/wp-content/uploads/2020/01/Blasting.mp4“][/video]
| Recommendations:
1. Explosions should only be conducted at times of the year when there are no nesting birds or harbour and elephant seals having young . 2. During the months of August, September and October when the sea lions are returning to the islands, they are particularly sensitive to disturbances. 3. December, March and April are probably the times of least impact but only if explosion size is carefully controlled. 4. The sizes of explosions should be carefully monitored so as to limit the impact of disturbance. 5. Blasts should be spaced out to at least 10 minutes between detonation, and especially never three blasts in succession. This lessens the impacts on the animals. SAMPLE DAILY LOGS FROM RACE ROCKS WITH EFFECTS OF BLASTING ON ANIMAL BEHAVIOUR Thursday, November 22, 2001–MARINE LIFE: A typical November day weather wise however the Military detonation exercises on Bentinck Island were particularly disturbing for the Harbour Seals and Sea Lions. Once the blasting was done for the day the animals were still quite nervous and in fact when a Cuda Marine Whale Watching boat went by one rock (15:15-15:30) with approximately 120 sea lions hauled out over half of them stampeded into the water!” Thursday, January 17, 2002 Friday, January 18, 2002 Thursday, January 24, 2002 Addendum: |
| UPDATE: January, 2007: Recent blasting activities at Bentinck Island have flushed some of the birds and have scared some of the northern sea lions into the water. In general however we have observed that when they only do two blasts at more than a 1 minute interval, there is much less disturbance than three successive blasts. |
 DEMARCHI, MW AND MD BENTLEY. 2004. Effects of natural and human-caused disturbances on marine birds and pinnipeds at Race Rocks, British Columbia. LGL Report EA1569. Prepared for Department of National Defence, Canadian Forces Base Esquimalt and Public Works and Government Services Canada. 103 p.
Note in particular, the discussion of the results concerning the effects of blasting on the behaviour of sea lions.
|
MONITORING DEMOLITION TRAINING IMPACTS IN
MILITARY TRAINING AREA WQ ON SEA LIONS IN THE
RACE ROCKS ECOLOGICAL RESERVE, BRITISH COLUMBIA
PROGRESS REPORT #1 REVISEDOVERVIEW1
LGL Limited successfully completed 5 days of monitoring (28P30 
November and 1P2 December 2010) of demolition training (OfficerTs Course) in Exercise and Training area WQ. Monitoring comprised a day of pre-blasting, 3 days with blasting, and a day of post-blasting. We have not yet reviewed information on the sizes of the projects that were detonated, but expect that all were 4 slabs of C4 as per past courses. Projects within a run were spaced at a minimum interval of 5 min. Time between runs varied considerably (~0.4P3.2 hrs). All other ranges in WQ were inactive during monitoring. Weather was modestly overcast and unsettled. Although a gale warning was in effect for local waters during the first few days of the session, winds only reached 20 knots on one day (30 November); they were mostly below 10 knots for the session. Light rain fell at times, and swell height was moderate and high for most of the session. Seas were Beaufort 1P3. Air temperature ranged from 5P8 °C. As per the table below, numbers of sea lions fluctuated considerably within and between days in response to natural and human-caused disturbances. There were no California sea lions in the Reserve and only 1 northern elephant seal. Significant displacement of sea lions from a haulout was observed in response to a single ecotour boat on the pre-blasting day and in response to blasting on days when the range was active. Only one ecotour boat was observed during the 5-day session, but that boat caused a disturbance that saw all sea lions become active (heads up) and most (~100) animals scramble off the haulout. Steller sea lion response to blasting ranged
from modest increases in activity to complete haulout abandonment. The number of sea lions hauled out in the Reserve at the end of the session (i.e., at the end of the post-blast monitoring day) was practically identical to the number at the beginning of the session (i.e., 130 cf. 131).
The total at the end of the session was off by a modest 20 animals from the peak count during activity samples (i.e., 150) P a difference that could be accounted for by animals not in view from the tower at their new location atop Area 2P5 at the end of the session and animals
swimming near the haulouts. Although nearly all animals were on haulout Area 2P5 at the beginning and end of the session, they had shifted their position to the highest part of the haulout in response to large swells that inundated the lower reaches of the haulout. As of 7 December,
the upper reaches of Area 2P5 continued to be used by most of the sea lions in the Reserve (as evident from the LBPC web cam).
No further monitoring is anticipated until summer/fall 2011.
See the of the full report at lgl2010progreport.
See other LGL reports at:
http://www.racerocks.com/racerock/research/LGL_report/DNDreportbyLGL.htm
July 28 2008 Blasting by the DND sent the 5 newly returned sea lions into water. Slash hits the water to cruise by the dock. 18 Ecotour boats sited in channel close to sea lions (also later main dock where Slash was lying by boat house).
Aug 20. 2008: Three males, slash absent.
Sept. 23, 2008 One juvenile male elephant seal was up on the lawn by the science house.. Slash has not been around for some time now.
Oct. 27, 2008: possibly one male out on middle rock.
http://www.flickr.com/photos/66339356@N00/2965657528/in/set-72157607795979132/
For November of 2008 they have been absent. We expect them back in mid December.
Data Compiled by Garry Fletcher, Nov. 29, 2008
“The Rock was ours.” Race Rocks Weekend
article and photos by Jeremias Prassl with group Naja, Angie, Ahmad, Josh, Roberto
It was after a week of painful Mock exams (or Group IV projects…), that we made our way out to Race Rocks on a beautiful Friday afternoon. Mike and Carrol, the light house guardians, had gone to town for the weekend, and so The Rock was ours. Second Nature was packed up high with our bags, food and dive gear as we left Pearson with Garry. The task list for the weekend included digging a trench for a new camera, fulfilling all island duties, and doing underwater camera work during our dives.
Saturday started with a surprise visit: A military Zodiac pulled up the docks, and two commandos informed us that they were looking for “the explosive”.
As we soon figured out, a grey cylinder the Navy had lost off one of their vessels had been washed ashore at Race Rocks – and it was still active! But with their gear, the soldiers took care of it within a few minutes. For the rest of the morning we were busy with digging a trench in the rocky ground – we definitely earned the big lunch that followed. In the afternoon we strolled around the intertidal zone with our learned guide Josh, before we got ready for a dive. We were treated to the usual beauty of the Marine Protected Area underwater, and after our air had run out we went for a snorkelling trip. The day was finished by a chocolate fondue under the constantly turning light on top of the lighthouse.
When Mike and Carrol came back, they brought their grandchildren Mike and Chris, and we took them around for an exploration of the island, including the two female elephant seals lazily in the sun. When Garry came to pick us up after a second dive Sunday afternoon, we would’ve all done a lot to stay longer… for a few more days of our great weekend. A special thanks to Chris and Garry for all their assistance!
http://web.archive.org/web/20070710010854/http://peernet.lbpc.ca/thelink/040904/04aRaceRks.html
originally published at : http://peernet.lbpc.ca/thelink/040904/04aRaceRks.html
April 9 2004 The Link number 63
PART 35.2.2.6 Disturbance by Pedestrians and Domestic Animals
Observed pedestrian effects were confined to monitoring areas on Great Race Rock. Pedestrian traffic was fairly constant throughout the year with a daily average of nearly three events (Table 9). The Reserve’s caretakers had a dog that was observed outdoors infrequently on Great Race Rock. No wildlife displacement was observed in response to the dog. A domestic cat was observed outside the house on one occasion, but no disturbance was noted. Pedestrian traffic, other than that of the researchers associated with this study, was common and occurred on most days. The Reserve’s caretakers and their family members, staff and students affiliated with LBPC (Photo 14), maintenance personnel, DFO enforcement officers, and tourists constituted the pedestrian traffic on Great Race Rock during monitored days. Although a sign-in log is maintained by LBPC to track the number of human visitors to Great Race Rock, those data were not analyzed in this study. Pedestrians displaced seal and sea lions on Great Race Rock. Pedestrian-caused disturbances typically involved: intentional clearing of northern elephant seals off the boat launch; incidental displacement of harbour seals in monitored Sub-Areas A, B, C, and H (Photo 15; Figure 20); incidental displacement of California sea lions (Figure 22) and to a lesser extent, northern sea lions in monitored Sub-Area A (near the dock); and incidental displacement of gulls throughout Great Race Rock (Table 8). On one occasion, two tourists were observed wandering through a grassy area that was being used for nesting by glaucous-winged gulls (Photo 16).
Photo 14. Students and staff from Lester B. Pearson College were frequent visitors to Great Race Rock. California
sea lions, such as those near the end of the dock, were often displaced from the vicinity by boats and people.
18 September 2003.
Photo 15. Approximately 200 harbour seals moved quickly from the shore of eastern Great Race Rock into the water immediately after being apparently startled by a high-pressure power washer being operated by a resident of the
island. This photo shows some of those animals displaced from Sub-Areas A&B. 25 September 2003
Photo 16. Two tourists wander through an active glaucous-winged gull nesting area (Sub-Area H) on Great Race
Rock; causing disturbance and risking egg destruction by trampling. 25 May 2003.
5.2.2.7 Disturbance by Aircraft
Very low numbers of aircraft were observed in or near the monitored area throughout the
monitored period (Figure 17; Photo 17). Most aircraft passed over or near the monitored area,
causing little or no apparent disturbance to wildlife (Table 8). Only one landing on the helipad on
Great Race Rock was observed. In January 2003, a Coast Guard helicopter did a brief landing in
order that we have an opportunity to observe the responses of birds and mammals. Some sea
lions, cormorants, and gulls were displaced. As reported by the ecoguardians in the 11 August
2003 entry of the Race Rocks Daily Log11 (a day on which LGL researchers were not present),
“A Coast Guard helicopter touched down several times, forcing young birds into other nests
where the adult birds pecked them apart. The disembodied heads and dismembered bodies of
seagull chicks now litter the island.” On 15 August 2003 we observed the carcasses of 6
glaucous-winged gull chicks near the eastern base of the light tower. An aerial survey of
pinnipeds was conducted by DFO from a fixed-wing aircraft occurred on 10 April 2003. That
plane circled over Race Rocks for approximately 4 minutes at an estimated minimum altitude of
150 m asl. No birds were observed to flush, nor were any pinnipeds seen going into the water as
a result.
Photo 17. Most aircraft overflights did not cause animals to leave the rocks for the water or air. 17 October 2002.
5.2.2.8 Disturbance by Boats
Kayakers were rare in the monitored area. Only birds were observed (once) flushing in response
to the approach of a kayak. Boats operated by LBPC were observed regularly throughout the
monitored period (Figure 17), and together with the LGL boat, were the only boats to regularly
dock at Race Rocks. LBPC and LGL boats displaced modest numbers of birds and pinnipeds
from the dock area during most arrivals and departures (Table 8). Displaced animals included
California sea lions in Sub-Area A; northern sea lions in Sub-Areas A, 2-5, and 8-12; cormorants
and gulls from Great Race Rock and Sub-Area 2-5. Most trips by LBPC boats were between
Pedder Bay and the dock at Great Race Rock, via routes through the east-central part of the
reserve (Figure 25). Some illegal harvesting of fish and shellfish by recreational fishermen and
recreational scuba divers, respectively was observed during the study.
Figure 25. Relative distribution of Lester B. Pearson College boats observed in Race Rocks Ecological Reserve
during monitoring sessions from October 2002 through November 2003. Numbers represent observations in each
cell expressed as a percentage of the maximum total number (57) observed in a given cell. Colour coding: 0=blank;
>0-33.3=yellow; >33.3-66.7=orange; >66.7-100=red. Islands and the Ecological Reserve boundary are indicated.
Great Race Rock is identified as “GRR”. Note that for each separate trip to the area, vessels were recorded a
maximum of once in any given cell. Refer to Figure 2 and Figure 3 for further spatial information.
Pleasure boats (Photo 18) were observed throughout the monitored period, but were most
common during summer (Figure 17). Harbour seals, sea lions, and cormorants, were all
displaced by pleasure boaters (Table 8; Figure 20; Figure 22; Figure 24). Observations indicated
that rental boats and boats used for scuba diving typically caused the most disruption because
they approached haulouts the closest and sometimes anchored (contrary to regulations) near
haulouts. Most trips by pleasure boats were in the northern part of the Reserve (Figure 26).
Figure 26. Relative distribution of pleasure boats observed in Race Rocks Ecological Reserve during monitoring
sessions from October 2002 through November 2003. Numbers represent observations in each cell expressed as a
percentage of the maximum total number (43) observed in a given cell. Colour coding: 0=blank; >0-33.3=yellow;
>33.3-66.7=orange; >66.7-100=red. Islands and the Ecological Reserve boundary are indicated. Great Race Rock is
identified as “GRR”. Note that for each separate trip to the area, vessels were recorded a maximum of once in any
given cell. Refer to Figure 2 and Figure 3 for further spatial information.
Ecotour boats constituted the greatest amount of boat traffic in the monitored area, with peak visitation rates during the height of the summer tourist season (Figure 17; Photo 19). Daily numbers of ecotour boats ranged from 0 to 43, with as many as nine present in the study area at the same time. Some ecotour boats were observed to displace harbour seals, sea lions, cormorants, and gulls (Table 8; Figure 20; Figure 22; Figure 24), but most caused no observable effects. According to VHF radio communications among ecotour boat operators on marine channels 71 and 72, the presence of ecotour boats in the monitored area was a function of the location of killer whales within the ecotour operating region. For example, if killer whales were near the San Juan Islands, few if any ecotour boats travelled to Race Rocks. If killer whales were in the vicinity of Race Rocks, operators usually toured the Reserve. If no killer whales were known to be in the region, operators toured the Reserve as a “next-best” option. Most trips by pleasure boats were in the central part of the Reserve, focused on Sub-Areas 1, 2-5, 6-7, 8-12, and northern Great Race Rock (Figure 27).
Figure 27. Relative distribution of ecotour boats observed in Race Rocks Ecological Reserve during monitoring
sessions from October 2002 through November 2003. Numbers represent observations in each cell expressed as a
percentage of the maximum total number (211) observed in a given cell. Colour coding: 0=blank; >0-33.3=yellow;
>33.3-66.7=orange; >66.7-100=red. Islands and the Ecological Reserve boundary are indicated. Great Race Rock is
identified as “GRR”. Note that for each separate trip to the area, vessels were recorded a maximum of once in any
given cell. Refer to Figure 2 and Figure 3 for further spatial information.
5.2.2.9 Disturbance by Blasting
Observations of the effects of blasting on birds and pinnipeds were made during days when at
least one of the three ranges was active. Because so few observations were made during blasting in Whirl Bay (4 days) and on Christopher Point (1 day), the value of any inference made from
those data is limited. Further, on the only day that the Christopher Point Range was active,
blasting on that range had commenced prior to our arrival at Great Race Rock, precluding any
pre-blast observations. Additionally, blasting occurred on Bentinck Island that day also (Table
1). On one of the days that Whirl Bay was active, Bentinck Island was also active.
None of the data we collected suggested that blasting in Whirl Bay had any adverse effects on bird or pinniped behaviour in the study area (Table 8, Figure 19, Figure 21, Figure 23).(See Editor’s comments in the discussion below )
Some blasts in Whirl Bay were barely audible to us outside the top of the light tower and a spray of
water was occasionally observed.
The Christopher Point Range was active on 11 days during the study period. Four to 20
ordnances were detonated per day, most of which were <100 g (Appendix 9). Blasting monitored
on Christopher Point occurred at a time (20 February 2003) when few birds and pinnipeds were
in the study area (Figure 6 through Figure 12). Four basic charges, 454 g each, were detonated
separately. The first blast we heard was clearly audible and occurred just as we were arriving at
Race Rocks. Approximately 10 northern sea lions were observed leaving a haulout, apparently in
response to the blast. Some sea lions remained in the water near Sub-Area 8-12 all day, but were
not observed to haul out again that day.
Blasting on Bentinck Island was the most frequent form of blast-related, potential disturbances
observed (Figure 18). That range was active with demolition activities throughout the study
except mid-June through early October 2003, due to an extreme fire hazard caused by prolonged
drought. Demolitions on Bentinck Island are tabulated in Appendix 8. In summary, blasting
occurred on Bentinck Island on 26 days (5.2%) of the 502 day period 13 July 2002 through 27
November 2003.
6 DISCUSSION
6.1 Relevant Legislation
A number of provincial, federal, and international acts have direct implications for the
conservation of marine life in Race Rocks Ecological Reserve (Appendix 1). Presently,
legislation contained within the federal Fisheries Act (by way of the Marine Mammal
Regulations), the Canadian Environmental Assessment Act, the Migratory Birds Convention
Act, the provincial Wildlife Act, and the provincial Ecological Reserve Act have the greatest
relevance for human-caused influences on wildlife in Race Rocks Ecological Reserve. The
federal Species at Risk Act and the Oceans Act are likely to play an increased role in the future
given the recent trend in concern about some species (e.g., killer whales and northern sea lions)
and in the event that Race Rocks achieves Marine Protected Area status.
A strict interpretation of the Fisheries Act, Migratory Birds Convention Act, the Wildlife Act and
the Ecological Reserve Act would indicate that these acts are violated regularly within Race
Rocks Ecological Reserve by factors within the Reserve (e.g., boats and people) and by factors
outside the Reserve (i.e., military exercises involving ordnance). In addition to several violations
of the tidal waters fishing regulations (under the Fisheries Act) events we witnessed during the study, human activities frequently disturb and disrupt bird and mammal activity patterns. Such factors are discussed in greater detail in subsequent sections.
Best practices of dive vessels, divers, tour operators (Province of BC 2002; Appendix 1) are
voluntary guidelines for the conduct of selected recreational activities within Race Rocks
Ecological Reserve. Those guidelines cannot eliminate adverse effects of boats on marine life,
but they can reduce them. While we did not collect detailed data on all aspects of compliance
with those guidelines, it was apparent to us that the guidelines were often not followed by boat
operators and others in the Reserve. In general, commercial tour boats conformed best to the
guidelines—perhaps due to an awareness of the guidelines and the importance of proper conduct
on the part of the boat captains. On the other hand, dive vessels and pleasure boaters were more
likely to operate in a manner inconsistent with the guidelines.
The people who live on Great Race Rock serve as “ecoguardians” in the employ of LBPC and
are charged with ensuring that the laws pertaining to the Reserve are respected. The
ecoguardians have no authority to enforce any of legislation listed above, but do attempt to
prevent or stop people from violating laws by confronting them and informing them of the
situation. The ecoguardians also report infractions and apparent infractions to the Department of
Fisheries and Oceans. Two Department of Fisheries and Oceans enforcement officers visited
Race Rocks via boat on one occasion (23 January 2003) during the days we monitored. Their
presence that day displaced two northern sea lions, 12 cormorants, and 13 gulls.
6.2 Use of Race Rocks by Marine Birds and Pinnipeds
The biophysical environment of Race Rocks provides habitat for many species (Table 3;
Appendix 5). The value of the area for foraging by marine birds appears modest compared to the
value of nearby areas outside the Reserve. The value of the area for foraging by marine
mammals is not known. We observed seals and sea lions feeding on salmon and unidentified fish
species, and harbour seals were observed once feeding on an octopus. Northern elephant seals
appear to be using the area mainly during the moulting seasons. Harbour seals use the area as a
haulout year-round, but that species does not exhibit the same degree of site selection as the three
other pinniped species. For example, harbour seals are the only pinnipeds that haul out on the
nearby shores of Bentinck and Vancouver islands. The area serves as a staging site for California
sea lions passing through Juan de Fuca Strait en route to the Strait of Georgia and Puget Sound.
Race Rocks is also a wintering, and perhaps staging area for northern sea lions. Killer whales use
the area occasionally as part of their movement corridor and possibly for foraging though we
made no such observations.
The fact that Race Rocks provides highly suitable habitat for marine birds and pinnipeds is
indisputable. However, an assessment of the extent to which Race Rocks provides important or
critical habitat for any given species is not so straightforward. According to the Species at Risk
Act:
“Critical habitat is habitat which is necessary for the survival or recovery of a
listed wildlife species and that is identified as the species’ critical habitat in the
recovery strategy or in an action plan for the species.” For species that are not listed under the Species at Risk Act, we use the term critical habitat to
refer to any habitat that is essential to the life processes of a species and that in the absence of
that habitat, the population would suffer detectable adverse effects.
In this context, it is not clear to what extent the population sizes of marine birds and pinnipeds
that presently occur in or that migrate through or over the waters of Juan de Fuca Strait and the
Strait of Georgia would differ in the absence of the exposed land in Race Rocks Ecological
Reserve. For example, while Race Rocks provides harbour seals, pigeon guillemots, black
oystercatchers, and glaucous-winged gulls with suitable breeding habitat, such habitat occurs
elsewhere in the marine areas of the Georgia Depression Ecoprovince (e.g., Campbell et al 1990
a, b; Jeffries et al. 2000; Evenson et al. 2001; Chatwin et al. 2002; Sullivan et al. 2002).
However, there are few if any areas like Race Rocks that provide suitable breeding habitat and
that are presently unoccupied. As such, the loss of Race Rocks likely could result in reduced
population sizes for species that breed there.
6.2.1 Birds
Gulls and cormorants, the most abundant birds in Race Rocks Ecological Reserve, typically used
the area as a resting site from which they would fly to marine feeding areas within a few
kilometres. Depending on the species, the Reserve provides breeding, staging, wintering, and
year-round habitat. The area provides nesting habitat for glaucous-winged gulls, pigeon
guillemots, and black oystercatchers, and serves as migration/staging and wintering habitat for
several species of gulls and three species of cormorants. Most use by shorebirds appears to be for
migration/staging.
6.2.2 Northern Elephant Seal
Use of Race Rocks by northern elephant seals has increased substantially in recent years, most
likely as a result of the species dramatic recovery from near extinction in the early 20th century
and the species’ tendency to be highly migratory. The peak number (22) of adults and subadults
observed in spring 2003 may well represent a record number for BC during recorded history. In
recent years, northern elephant seal pups have been sighted at haulouts in the inland waters of
Washington State (Jeffries et al. 2000) and at least three are reported to have been born there
(Hayward 2003). It is likely that numbers of northern elephant seals using Race Rocks will
continue to increase. Given the recent records of breeding in Washington (Hayward 2003), Race
Rocks might be used for pupping, though it is unlikely that it would ever become a breeding
rookery of any significance—especially as long as there is infrastructure on Great Race Rock.
The primary value of Race Rocks for this species will likely remain as a haulout for a modest
number of animals during seasonal moulting periods, but because such a small fraction of the
population occurs there, it is unlikely that the Reserve provides the species with any critical
habitat.
6.2.3 Harbour Seal
Harbour seals occur year-round at Race Rocks, and use the area for all aspects of their life
history. Whereas northern elephant seals and sea lions moved to locations above the high tide
level on haulouts in the study area during flood tides, harbour seals remained confined to
intertidal areas where they were displaced by tides, swells and waves. Thus, their numbers exhibited considerably greater fluctuations at hourly, daily, and seasonal time scales compared to
other pinnipeds in the area. Numbers hauled out in the study area peaked during the summer
pupping and moulting periods, which is consistent with other research on the species (e.g.,
Jeffries et al. 2003).
Numbers of harbour seals have rebounded since the end of Canadian and U.S. government-
sponsored culling programs prior to the early 1970s. The result of this increase is that numbers of
harbour seals in the Georgia Depression Ecoprovince are likely as high as they were prior to the
onset of the culls and may be at or very near the predicted carrying capacity of local habitats. For
example, Olesiuk et al. (1990) estimated that from 1973-1987 (the period they examined)
harbour seals in British Columbian waters had a mean annual rate of increase of 12.5%, resulting
in nearly a 10-fold increase in numbers. Those authors speculated that 12.5% annual population
growth was close to the maximum intrinsic growth rate of the species. Similarly, Jeffries et al.
(2003) calculated that harbour seals in nearby Washington State waters increased 7-10 fold
between 1970 and 1999 and that the population of harbour seals in Washington State could
decline by up to 20% and still be above the maximum net productivity level for the population.
Harbour seals are known to move across the international boundary in the Georgia Depression
Ecoprovince (Huber et al 1993, cited in Calambokidis and Baird 1994). Clearly, there are no
reasons for concern about local harbour seal conservation based on population status alone.
Numerically speaking, the local population is in good shape and there is an abundance of high-
suitability habitat elsewhere in the Georgia Depression Ecoprovince (Jeffreies et al. 2000). Thus,
it is unlikely that Race Rocks Ecological Reserve presently provides critical habitat for this
species.
Bioaccumulation of anthropogenic toxins and their effects on immune-responses and fertility of
harbour seals is a subject matter that is receiving increased attention—particularly because of
parallel concerns about killer whales (see Calambokidis et al. 1994 and references therein).
However, we are not aware of any empirical data that presently indicate that toxins are adversely
affecting total numbers of harbour seals in the Georgia Depression Ecoprovince.
6.2.4 California Sea Lion
The number of California sea lions in British Columbian coastal waters has increased
substantially during the latter 20th century, particularly since 1980 (Bigg 1988a). The species
does not breed in BC, nor are there any records that it did so in the past. This increase is also the
result of a rebound in numbers following the termination of government-sponsored culls. Bigg
(1988a) reported that California sea lions were not present on Race Rocks prior to 1965.
Numbers have increased since then. P. Olesiuk (pers. comm. 2002) indicated that California sea
lions are expanding their non-breeding range northward within BC. Little is known of this
expansion, or of its present or future impacts on other marine resources. The patterns of
abundance at Race Rocks observed during this study indicate that the value of Race Rocks for
this species is primarily as a migration/staging area. California sea lions migrate to BC from
southern waters (e.g., California) then move between various haulouts and feeding areas,
including Race Rocks. Range expansion to the north may also explain the apparent decline in
peak numbers occurring at Race Rocks. An apparent increase in the use of the Victoria
waterfront and Trial Island haulout by California sea lions may partially explain an apparent
decline in use of Race Rocks by that species in autumn 2002. For example, data in Bigg (1988a) indicate that numbers of California sea lions at Race Rocks during February (not the peak month
according to recent data) increased from 13 in 1978 to 320 in 1982, to 799 in 1984. Demarchi et
al. (1998) reported a peak count of 836 in October 1997. In the present study, peak counts were
considerably lower at 244 individuals in September 2003. It is unlikely that Race Rocks
Ecological Reserve presently serves as critical habitat for this species.
6.2.5 Northern Sea Lion
The number of northern sea lions in British Columbian coastal waters has increased substantially
during the latter 20th century, and in particular, since 1980 (Bigg 1988b). This increase is also the
result of a rebound in numbers following the termination of government-sponsored culls. Recent
trends in the abundance of northern sea lions suggest an average annual rate of increase of 3.2%,
resulting in a population size that is more than double what it was when the species was
protected in 1970 (P. Olesiuk, unpublished data). No new breeding rookeries have been
established in recent years. Numbers of northern sea lions using Race Rocks have also increased
since culling ended. For example, Bigg (1988b) indicated that prior to 1965, northern sea lions
had not been recorded at Race Rocks. In 1971, no more than 71 northern sea lions were recorded
there. In 2002 we recorded a maximum count of 528 and in 2003, 555 individuals (Figure 12).
Observations made during this study indicate that numbers of northern sea lions at Race Rocks
fluctuate seasonally. Our findings concur with those of Bigg (1988b), who identified Race Rocks
as a winter haulout. Adult males are first to arrive in late summer. Females, subadults, and young
arrive later, with total numbers peaking in early winter. Though pups born at distant rookeries
were seen at Race Rocks, nursing behaviour was observed only occasionally. As winter
progressed animals began to leave the area and by late February few if any were present. This
pattern indicates that the area is used as a wintering site and may also serve as a
migration/staging area for animals moving between the Strait of Georgia, Juan de Fuca Strait,
and outer coastal areas north and south of Juan de Fuca Strait.
Of the four species of pinnipeds that commonly occur at Race Rocks, only the northern sea lion
might be considered to be presently using the area as critical habitat. This opinion is predicated
on the following points: 1) the Western Stock of northern sea lions has exhibited a dramatic
decline in numbers in recent decades for unknown reasons. For the same reason(s), it is possible
that the Eastern Stock could also decline in the future; 2) Despite data suggesting that the
population is growing at a modest rate, the northern sea lion has recently been up-graded by
COSEWIC to a species of Special Concern and has been Red-Listed by the Province for several
years.
6.3 Effects of Natural and Human-Caused Disturbance
Animals respond to changes in environmental conditions for many different reasons and in many
different ways. This study focuses on only two responses to disturbance: increased activity
(pinnipeds only) and displacement from a terrestrial site to the air (birds) or water (birds and
pinnipeds). During this study it was clear that Race Rocks Ecological Reserve is exposed to
substantial fluctuations in many natural factors—often over very short time scales. Factors
operating at or below a daily time scale, including changes in tide and swell height, blasting on
Bentinck Island and human-caused disturbances on Great Race Rock exerted strong influences on the abundance of some species. None of the data we collected suggested that blasting in Whirl Bay had any effects on bird or pinniped behaviour in the study area. Although Demarchi et al. (1998) did observe northern sea lions responding to blasts in Whirl Bay, C-4 charges detonated during that study were considerably larger (thus, louder) than those used on the range during this
study. At best, some of the blasts in Whirl Bay were barely audible to us outside the top of the
light tower and a spray of water was occasionally observed. Insufficient monitoring during days
when the Christopher Point Range was active limits our ability to draw conclusions about the
effects of such blasting on birds and pinnipeds at Race Rocks. It should be noted that explosions
in WQ are not the only shore-based ones with the potential to disturb marine birds and pinnipeds
near southern Vancouver Island. The fireworks display at Butchart Gardens on Saanich Inlet
(approximately 32 km to the north) each Saturday evening during summer results in a
considerable amount of explosives-generated noise near the marine environment. Additionally,
there are fireworks associated with Canada Day, BC Day, and Halloween. Blasting in rock
quarries and for highway construction also occur periodically on southern Vancouver Island. The
potential for the foregoing to disturb marine wildlife is substantial, though the actual effects are
unknown.
| Editor’s Note: This discussion of the results of DND Blasting is somewhat problematic and perhaps the result of too few observations by the research team when actual blasting was taking place. It must be noted that most of the blasting events occurring during the year of the study were not observed and recorded by the researchers. The following two references point to some archival footage that may lead to different conclusions:
https://www.racerocks.ca/before-and-after-images-of-dnd-blasting-effects/ DND Blasting Disturbs sea lions DND Demolition Blasts affects Mammals and Birds at Race Rocks |
The purpose of examining how marine birds and pinnipeds at Race Rocks responded to changing
environmental conditions and human-caused disturbances is to provide a better understanding of
the local ecological environment, and allow management actions to be sensitive to normal
processes. There are many reasons why animals respond to disturbances. Responses to
disturbance by birds and pinnipeds at Race Rocks are most likely the result of learning
experiences elsewhere or simply the result of reactions to sudden changes in the environment.
For example, not long ago, seals and sea lions were hunted extensively as vermin. Outside Race
Rocks Ecological Reserve animals continue to be shot and shot at for First Nations’ harvesting,
animal control at aquaculture facilities (Hume 2000), and as perceived pests and competitors by
commercial fishermen. Gulls and cormorants are also shot and shot at for purposes of wildlife
control at some airports and may be shot at by waterfowl hunters. As long as animals are
persecuted with firearms they can be expected to associate loud noises with danger; responding
by becoming alert and moving to the relative safety of the air or water. Such behaviour would be
expected even though animals are not shot or shot at in the Race Rocks Ecological Reserve to
our knowledge.
Humans and their actions have the potential to disturb wildlife. The following classification is
based on Wilson and Shackleton (2001), who described 3 theoretical classes of animal responses
to disturbance:
Marine birds and pinnipeds at Race Rocks are exposed to a number of different disturbance
stimuli that alter normal behaviour patterns. The fact that human activities disturb wildlife does
not in itself provide a basis to ban such activities. Indeed, if that were the case, no people or
boats would be permitted in the Race Rocks Ecological Reserve without authorization. If
disturbances have no consequences for the population, or even if the population consequences
are sustainable, restricting human activities for the sake of preventing disturbance is likely to
have negative social consequences that are out of proportion to the impacts that are being
avoided or mitigated.
It is necessary to place the disturbance of marine life at Race Rocks into context in order to begin
to assess the significance of any adverse effects. The effects of disturbance can be viewed in a
hierarchical framework where effects on a population or species range from benign to severe
(Figure 28). Consequences of disturbance at the extremes of the range are obvious—stimuli that
do not elicit reactions are of no consequence while those that cause extirpation or extinction are
of great concern. Quantifying the existence and significance of the effects in-between these
extremes poses a far greater challenge. The US National Marine Fisheries Service
(50CFR216.103)12 defines a negligible impact as:
Ecoguardians resident on Great Race Rock provide a measure of protection for marine life in the Reserve, but the presence of inhabitants and infrastructure is not without impacts. In recognizing
some of those impacts, efforts are being taken to avoid or mitigate them (Province of BC 2002).
The infrastructure and various activities required to support the ecoguardians and the light station
undoubtedly affects use of the area by birds and pinnipeds and poses some risks to animals using
the area. Several potential effects are summarized below.
• Risk of fuel spill—Diesel required for the generators poses a risk of spill during fuel
transfer to the island and during storage and use on the island.
Figure 28. Conceptual model of the hierarchical effects of exposing a wildlife species to a non-directly lethal visual
or aural disturbance stimulus.
6.3.1 Birds
Of the birds observed on the rocks of the monitored area, cormorants appeared to be the most
sensitive to human-caused disturbances. Cormorants sometimes took to the water or air following a blast or close approach of a boat, often simply moving to another part of the study
area. The reduced probability of displacement in response to a blast on days when the
temperature was higher might have implied that warm weather was particularly valuable for
thermoregulation and that birds were reluctant to lose opportunities to dry their plumage or to
remain dry. The apparent avoidance of Great Race Rock by Brandt’s cormorants during winter
may suggest that that species is particularly sensitive to disturbances by people. However,
because cormorant attendance at the rocky areas of Race Rocks is normally very dynamic as
individuals move between terrestrial roosting areas and marine feeding areas, it is not possible to
assess the extent to which such disturbances adversely affect cormorants. Their continued
presence in the study area indicates that any adverse effects of disturbance are likely modest.
Gulls were very sensitive to overflights by bald eagles and often reacted by taking flight. In most
instances, gulls settled back within seconds or minutes of the disturbance. During the breeding
season, glaucous-winged gulls were particularly sensitive to the presence of people on Great
Race Rock and often acted very aggressively, dive-bombing at and defecating on anyone that
approached within a few meters of a nest. The influence of swell height on gull abundance at
Race Rocks (higher swells resulted in more gulls in the study area) might have reflected reduced
foraging due to unsuitable off-shore feeding conditions, reduced areas for loafing, and/or other
factors. It is also possible that some gulls moved to Race Rocks from the vicinity of Bentinck
Island during days when blasting occurred there.
Adult pigeon guillemots breeding on Great Race Rock commonly roosted on the periphery of the
island and on the dock during the morning. They were often flushed by boats and people, though
the birds usually returned soon after the disturbance had passed.
The apparent avoidance of Great Race Rock by bald eagles and Brandt’s cormorants is believed
to be in response to the presence of humans and the sensitivity of those species to disturbance.
However, we doubt that the maximum numbers of these species in the Reserve would be
significantly different in the absence of humans and infrastructure on Great Race Rock because
other resting areas exist in the Reserve.
Sullivan et al. (2002) speculated that disturbance and predation by bald eagles at glaucous-
winged gull colonies might be important factors contributing to the observed decline in the
reproductive output of those gulls in the Southern Strait of Georgia. Chatwin et al. (2002) made
similar conclusions regarding bald eagle impacts on pelagic and double-crested cormorant
colonies. Concerns about recent declines in numbers of glaucous-winged gulls and pelagic
cormorants at specific breeding sites in the southern Strait of Georgia may place increased
importance on the value of Great Race Rock as a breeding area, particularly for glaucous-winged
gulls. Because so few pelagic cormorants breed at Race Rocks and because breeding is sporadic
there, it is unlikely the area provides the species with critical nesting habitat. The situation at
Great Race Rock poses somewhat of a dilemma in this regard because on one hand, the presence
of buildings, infrastructure and people substantially reduces the area of land available for nesting
by glaucous-winged gulls. On the other hand, we suspect that the presence of people serves to
deter bald eagles from using Great Race Rock (see Table 2), thereby affording a measure of
protection to the gulls that do breed there. Race Rocks could be providing glaucous-winged gulls
with important nesting habitat that is relatively free of bald eagle disturbance. If other colonies
continue to decline, the importance of Race Rocks might increase in the future. However, it is unlikely that the Reserve presently provides critical habitat for glaucous-winged gulls. Further, while recent declines in numbers breeding at some colonies have been noted (Sullivan et al. 2002), the breeding population in the Georgia Depression Ecoprovince is believed to have doubled between 1960 and 1986 (Mahaffy et al. 1994). Expanded food availability at landfills and the fact that the species nests successfully on a number of human-made structures (e.g.buildings and structures associated with port facilities) have likely contributed to the increase (Vermeer et al. 1988).
6.3.2 Northern Elephant Seal
Of all pinniped species that occur at Race Rocks, northern elephant seals were the most tolerant
of any forms of disturbance we observed. Holst and Greene (2002) also found that military
training activities that generated noise elicited few noticeable reactions from northern elephant
seals. We did not detect any meaningful responses of northern elephant seals to either natural
factors or blasting. It is not known whether the decline in numbers of northern elephant seals that
occurred in the weeks following blasting on Bentinck Island in early May 2003 represented a
reaction to blasting or not. However, given the species’ lack of responses to blasting on a daily
time scale and the fact that animals hauled out at that time of year are expected to depart haulouts
following the moult, the decline was likely coincidental with blasting. The significance of the
complex interaction term of tide height, swell height, and blasting (Table 4) might reflect
increased afternoon counts of individuals that were present in the morning, but that were
previously hidden from view in the morning by sea lions that moved or departed the area in the
afternoon. It is also possible that the significance of the term is spurious. In any event, we found
nothing to suggest that northern elephant seals in the study area were adversely affected by
environmental factors or blasting in a meaningful way. Considering this and the status
information discussed in section 6.2.2, at present, no significant adverse effects stemming from
single or cumulative disturbance types on the regional population of this species are expected to
originate in or immediately adjacent to the study area.
6.3.3 Harbour Seal
In situations where most harbour seal activity did not proceed to the point of displacement,
blasting on Bentinck Island was the only factor that caused noticeable increases in harbour seal
activity (i.e., moving from a head-down to head-up position). Other factors such as pedestrians
caused increased activity. However, because animals moved quickly to the water in such events,
the sampling data do not reflect this as no counts were made between the time that the
disturbance occurred and the onset of displacement. Aside from seasonal effects, the abundance
of harbour seals in the study area was dictated primarily by tide height. As shown in Photo 11,
harbour seals were particularly sensitive to changes in tidal height because they selected
primarily the intertidal reaches of the study area for hauling out. Rising tides displaced harbour
seals from haulouts, while falling tides provided opportunities for hauling out. Harbour seals
haul out year-round, but the peak in this behaviour that occurs in the summer corresponds to two
biologically important events. First, harbour seals give birth while on land where mother-pup
pairs spend 90-100% of their time during the 4-6 week nursing period (Huber et al. 2001).
Second, each summer harbour seals moult (shed) their fur and grow a new coat. The fact that
harbour seals moult in the summer and that they haul out to do so likely reflects
thermoregulatory constraints (Ling et al. 1974). By hauling out, moulting seals reduce heat loss at a time when their coat provides the least amount of insulation. Also, basking in the summer
sun and on sun-warmed substrates heats the skin surface, likely increasing the metabolic rate of
hair follicles, thereby increasing the rate of hair growth. Evidence that thermal constraints affect
haulout behaviour is provided by seal responses during days when blasting occurred on Bentinck
Island. While greater numbers of projects (blasts) per run resulted in increased probability of
displacement, both swell height and air temperature also appeared to affect the probability of
displacement to the water. Following blasts on Bentinck Island, harbour seals were more likely
to go into the water when the air temperature was higher and the swell height was lower (Table
5). On cooler days with higher swells, harbour seals were more likely to remain hauled-out after
a disturbance stimulus possibly because of a relatively greater need for dermal warming at that
time. Despite variable reactions to individual blasting events, overall changes in the numbers of
harbour seals hauled out in the study area appeared to be adversely affected by blasting on
Bentinck Island, but the effect was not statistically significant. This was most likely because of
two reasons: 1) the dramatic effects of increased tide height masked any effects of blasting, and
2) small sample sizes. Although we were unable to observe seal responses to blasting during
summer because of a military range closure, the same pattern of declining abundance in response
to increased tide heights would have likely masked any effects of blasting. Data shown in Figure
14 suggest that with increased sample sizes, the effects of blasting on Bentinck Island would
likely have become statistically significant.
Harbour seals hauled out on Great Race Rock were usually very skittish in the presence of
humans. Seals near the dock (Photo 1; Sub-Areas A&H) seldom remained hauled out when boats
or people approached. Those on the east side of Great Race Rock (Sub-Areas B-D) were quick to
respond to human-caused disturbances that resulted in noise (e.g., an aluminum ladder dropped
on a concrete walkway, machinery starting up, close approaches by pedestrians). For example,
approximately 200 harbour seals moved quickly from the shore of eastern Great Race Rock into
the water immediately after a gasoline-powered high-pressure power washer started near the
caretaker’s residence.
Unlike the other pinnipeds in the study area, harbour seals do not undertake long-distance
migrations. A non-migratory life strategy is more conducive to a greater degree of familiarity
with certain aspects of an animal’s home range than is a migratory one. Harbour seals are long-
lived (up to 30 years; Bigg 1981) and individual harbour seals probably stay in the vicinity of the
study area year-round. Because the study area has been exposed to blasting, boats, and
pedestrians for many years, it is not unreasonable to assume that some harbour seals have
habituated somewhat to some disturbances there. The ability of harbour seals to habituate to
disturbances is supported by the fact that they are easily kept in captivity and exhibit a rapid
adjustment under restrained conditions (Bigg 1981). Harbour seals at Race Rocks, although
skittish in the presence of people, are more tolerant of close approaches by humans than are
harbour seals in areas where they are shot and shot at (M. Demarchi pers. obs.).
Harbour seals in Race Rocks Ecological Reserve exhibited short-term acute behaviours in
response to disturbances resulting from natural factors, blasting, boats, and pedestrians. Holst
and Greene (2003) made similar observations of harbour seals during noisy military training
exercises in California. The fact that such responses occur in response to human activities
indicates that disturbance (in the context of the Fisheries Act; or “takes” in the context of the US
Marine Mammal Protection Act) occurs. However, it is unlikely that any seals are seriously injured by any of the disturbances, nor is it likely that mother-pup pairs are permanently
separated resulting in dead pups, in a manner reported by Johnson (1977). We observed three
dead adult/subadult harbour seals on the shore of Great Race Rock, but did not observe any dead
pups during the study. Considering this and the status information discussed in section 6.2.3, no
significant adverse effects stemming from single or cumulative disturbance types on the regional
population of this species are expected to originate in or immediately adjacent to the study area.
6.3.4 California Sea Lion
Blasting on Bentinck Island and boat traffic increased the activity levels of California sea lions
hauled out in the study area. Pedestrians on Great Race Rock also caused increases in activity,
but usually fewer than ten animals were involved. Aside from seasonal effects, the abundance of
California sea lions in the study area was dictated primarily by swell height. As swell height
increased, so did the probability of a decline in abundance. According to the pattern of declining
abundance observed in autumn 2003 prior to blasting, the decline in numbers of California sea
lions following blasting in early October 2002 was more likely the result of natural migration
patterns than displacement due to disturbance (Figure 11).
Blasting on Bentinck Island, pleasure boats, and pedestrians all displaced California sea lions to
the water. Holst and Greene (2003) made similar observations of California sea lions during
noisy military training exercises in California. California sea lions were increasingly likely to be
displaced due to blasting on Bentinck Island with greater numbers of projects in a run and when
wind directions acted to amplify blast noise. Tide height did not appear to influence the
abundance of hauled-out California sea lions because they typically hauled out above the
intertidal zone. Pleasure boats that approached haulouts too closely were observed to displace
animals. California sea lions hauled out on Great Race Rock usually tolerated the presence of
humans nearby, but there was consistent displacement involving animals moving off the dock
and nearby shore in response to boats and pedestrians. It was occasionally possible to dock a
boat without displacing all individuals nearby, possibly because those animals had habituated to
such disturbances (Photo 14).
California sea lions in Race Rocks Ecological Reserve exhibited short-term acute behaviours in
response to disturbances resulting from natural factors, blasting, boats, and pedestrians. Such
responses to human activities indicates that disturbance (in the context of the Fisheries Act; or
“takes” in the context of the US Marine Mammal Protection Act) occurs. However, it is unlikely
that any animals are seriously injured by any of the disturbances. Considering this and the status
information discussed in section 6.2.4, at present, no significant adverse effects stemming from
single or cumulative disturbance types on the regional population of this species are expected to
originate in or immediately adjacent to the study area.
6.3.5 Northern Sea Lion
Blasting on Bentinck Island increased activity of hauled-out northern sea lions throughout the
study area. Animals in Sub-Areas 2-5, 6-7, 8-12, and 13 (i.e., closer to Bentinck Island) were
particularly sensitive. Animals in those sub-areas were also exposed to the greatest amounts of
boat traffic. Despite this, we did not observe any obvious shifts in animal distribution to areas
that were not as prone to disturbance by blasting and boats (e.g., Sub-Areas 14; 15-24).
Pedestrians on Great Race Rock also caused increases in activity, but usually fewer than ten animals were involved. Aside from seasonal effects, the abundance of northern sea lions in the
study area did not appear to be predictably influenced by any given factor. On several occasions,
northern sea lion activity increased substantially and many animals moved to the water, yet we
could not clearly identify any disturbance stimuli. In one such case, the only apparent cause was
the sudden appearance of the sun as a cloud moved past. Such behaviours have been observed by
others (e.g., Porter 1997). We speculate that those events are likely triggered by the actions of
one animal that, for whatever reason, panics. The effects of that animal cascade through the
group, prompting similar behaviours in others. Such events are likely inevitable for species that
occur in groups where such groups confer a measure of safety in that danger does not have to be
detected by every animal in order for an appropriate response to occur.
Disturbances caused by blasting on Bentinck Island, pleasure boats, and pedestrians all displaced
northern sea lions to the water. Of all species monitored, the northern sea lion was most sensitive
to blasting on Bentinck Island. During 43 demolition runs, 1 animal was observed to be
displaced to the water in response almost 91% of the time. In a few instances, haulouts were
completely cleared of northern sea lions. Because of this high rate of response, no natural factors
were found to significantly affect animal responses. Tide height did not appear to influence the
abundance of northern sea lions because, like northern elephant seals and California sea lions,
they typically hauled out above the intertidal zone or moved to higher points on the haulout
during flood tides. Pleasure boats that approached haulouts too closely were observed to displace
northern sea lions. Northern sea lions hauled out on Great Race Rock were less tolerant of the
presence of humans nearby, as there was consistent displacement involving animals moving off
the dock in response to boats and pedestrians.
The decline of the Western Stock of northern sea lions in the Gulf of Alaska and Aleutian Islands
in the late 1970s and 1990s is presently a matter of intense research13. Investigations into the
causes of the decline involve a number of hypotheses, including nutritional stress (Trites and
Donnelly 2003), human-caused disturbance (L Kucey14, in progress), and predation by killer
whales following a decline in whale prey as a result of excessive commercial whaling in the past
(Springer et al. 2003). While there is presently no consensus on the cause(s) of the decline,
Pascual and Adkinson (1994) concluded that only a long-term change in the environment or
novel catastrophe would be capable of causing the magnitude of the observed decline. Pascual
and Adkinson (1994) note the difficulty in eliminating human-caused disturbance as a causative
factor because human activity in the region has increased simultaneously with the decline in sea
lion numbers. However, if disturbance was the primary cause, one should expect the Eastern
Stock (of which animals at Race Rocks are part) to have exhibited a similar, if not more
pronounced decline because of perhaps an even greater increase in human activities within their
range. Springer et al. (2003) favour the predation hypothesis over others such as nutritional stress
and disturbance for several reasons. According to them:
13 refer to: http://nmml.afsc.noaa.gov/AlaskaEcosystems/sslhome/StellerHome.html
14 refer to: http://www.marinemammal.org/MMRU/laura.html
While we did not examine body condition of northern sea lions closely, in our opinion, the
individuals at Race Rocks did not exhibit any signs of malnutrition (e.g., lethargic behaviour,
emaciated bodies with visible bone structure).
Northern sea lions in Race Rocks Ecological Reserve exhibited short-term acute behaviours in
response to disturbances resulting from natural factors, blasting, boats, and pedestrians. The fact
that such responses occur in response to human activities indicates that disturbance (in the
context of the Fisheries Act; or “takes” in the context of the US Marine Mammal Protection Act)
occurs. Although we observed a few subadult males with cuts and patches of missing skin, such
injuries likely resulted from fights with each other. It is unlikely that any animals are seriously
injured by any of the disturbances. Despite the species’ sensitivity to blasting, displaced
individuals typically began returning to the haulout within minutes or hours of the disturbance,
indicating that they were not displaced from the study area or very far from it (this study;
Demarchi et al. 1998). The fact that Race Rocks is not a rookery for this species means that the
risks of pup abandonment or trampling due to blast-caused disturbances (e.g., stampedes) are
very low. Considering the foregoing and the status information discussed in section 6.2.5, no
significant adverse effects stemming from single or cumulative disturbance types on the regional
population of this species are expected to originate in or immediately adjacent to the study area.
7 CONCLUSIONS
The fact that Race Rocks provides highly suitable habitat for marine birds and pinnipeds is
indisputable. However, the Northern Sea Lion (COSEWIC, Special Concern; Conservation Data
Centre, Red Listed) is the only species that could be reasonably expected to pose any local
conservation concerns at Race Rocks at present. The black oystercatcher (COSEWIC, Not
Listed; Conservation Data Centre, Yellow Listed) might become a concern in the future at Race
Rocks due to the relatively low number of breeding pairs in the province.
Marine birds and pinnipeds at Race Rocks are exposed to a number of different disturbance
stimuli that alter normal behaviour patterns. The fact that human activities disturb wildlife does
not in itself provide a basis to ban such activities. Indeed, if that were the case, no people or
boats would be permitted in the Race Rocks Ecological Reserve without authorization. If
disturbances have no consequences for the population, or even if the population consequences are sustainable, restricting human activities for the sake of preventing disturbance is likely to have negative social and other consequences that are out of proportion to the impacts that are being avoided or mitigated.
According to the findings of this study, no significant adverse effects stemming from single or
cumulative disturbance types on the regional populations of any species of marine bird or
pinniped at Race Rocks Ecological Reserve are expected to presently originate in, or
immediately adjacent to, the study area. This is consistent with Holst and Greene (2003), who
concluded that, despite eliciting behavioural responses, noisy military training exercises in
California only had minor, short-term, and localized, effects on pinnipeds, with no consequences
for the pinniped populations.
.15. During the study, we observed three dead harbour seals, one dead northern sea lion, and two California sea lions with potentially life-threatening internal injuries. Both California sea lions were emaciated and exhibited lethargic, abnormal behaviours. A number (<20) of other sea lions were observed with various anthropogenic materials (e.g., nets, rope and other closed-loop materials, fishing gear) around their heads, necks or torsos, or in the case of fishing gear, hanging from their mouths. While some of those animals would likely die from their entanglement, none appeared to be near-death when we observed them. One subadult male northern elephant seal was severely cut up, but was observed several months later, mostly healed. One male California sea lion had a severe injury to one front flipper. Several northern sea lion males were observed with what appeared to be non-life- threatening dermal wounds (i.e., torn or missing skin) on their chests.
Prepared for
Department of National Defence
Canadian Forces Base Esquimalt
Victoria, BC &
Public Works & Government Services Canada
Pacific Region Victoria, BC
Prepared by Mike W. Demarchi (M.Sc. R.P.Bio.) and Michael D. Bentley
LGL Limited
environmental research associates
9768 Second Street Sidney, BC V8L 3Y8
Cover photo: northern sea lions hauled out in Race Rocks Ecological Reserve, November 2003
EXECUTIVE SUMMARY
On behalf of the Department of National Defence and Public Works & Government Services Canada, LGL Limited conducted a 14-month assessment of natural and human-caused factors with potential to affect key species of marine birds and pinnipeds at Race Rocks, British Columbia.
This study had the following objectives:
During 6 October 2002 through 27 November 2003, 52 monitoring sessions were conducted. Many different weather conditions, sea conditions, and human-caused disturbance events were observed. Tidal conditions changed considerably on hourly, daily and seasonal timescales. Animal distributions in the study area were very aggregated and showed clear patterns of seasonal variation.
The Federal and Provincial status of key wildlife species, together with a brief species account of each were presented. Species that are common at Race Rocks use the area to fulfil life history needs including, non-breeding seasonal ranges, breeding habitat, migration/staging, and moulting. Important uses of the area by common species are summarized in the table below. Race Rocks provides highly suitable habitat, but with the possible exceptions of northern sea lions and black oystercatchers, the area is not likely providing any species with critical habitat (see page 55) at present.
Northern elephant seals were the least abundant pinniped throughout the study. Maximum daily counts ranged from 0 in the late autumn to 22 in the spring. Harbour seals were the most abundant pinniped throughout the study. Maximum daily counts ranged from 0 in the winter to 667 in the summer. California sea lions were the third most abundant pinniped during study. Maximum daily counts ranged from 0 in the winter and summer to 244 in late summer.
Northern sea lions were the second most abundant pinniped during the study. Maximum daily counts ranged from 0 in the summer to 555 in late autumn. Although the northern sea lion is Red Listed in British Columbia, all individuals that occur at Race Rocks are believed to be from the Eastern Stock. Whereas the Western Stock is listed as Endangered under the U.S. Marine Mammal Protection Act, the Eastern Stock is not.
|
Cover photo: northern sea lions hauled out in Race Rocks Ecological Reserve, November 2003 EXECUTIVE SUMMARY On behalf of the Department of National Defence and Public Works & Government Services Canada, LGL Limited conducted a 14-month assessment of natural and human-caused factors with potential to affect key species of marine birds and pinnipeds at Race Rocks, British Columbia. This study had the following objectives:
During 6 October 2002 through 27 November 2003, 52 monitoring sessions were conducted. Many different weather conditions, sea conditions, and human-caused disturbance events were observed. Tidal conditions changed considerably on hourly, daily and seasonal timescales. Animal distributions in the study area were very aggregated and showed clear patterns of seasonal variation. The Federal and Provincial status of key wildlife species, together with a brief species account of each were presented. Species that are common at Race Rocks use the area to fulfil life history needs including, non-breeding seasonal ranges, breeding habitat, migration/staging, and moulting. Important uses of the area by common species are summarized in the table below. Race Rocks provides highly suitable habitat, but with the possible exceptions of northern sea lions and black oystercatchers, the area is not likely providing any species with critical habitat (see page 55) at present. Northern elephant seals were the least abundant pinniped throughout the study. Maximum daily counts ranged from 0 in the late autumn to 22 in the spring. Harbour seals were the most abundant pinniped throughout the study. Maximum daily counts ranged from 0 in the winter to 667 in the summer. California sea lions were the third most abundant pinniped during study. Maximum daily counts ranged from 0 in the winter and summer to 244 in late summer. Northern sea lions were the second most abundant pinniped during the study. Maximum daily counts ranged from 0 in the summer to 555 in late autumn. Although the northern sea lion is Red Listed in British Columbia, all individuals that occur at Race Rocks are believed to be from the Eastern Stock. Whereas the Western Stock is listed as Endangered under the U.S. Marine Mammal Protection Act, the Eastern Stock is not. Within seasons, weather and sea conditions affected the abundance of some bird and pinniped species, and the probability that a disturbance event would disturb some species to the point of displacement. Pinnipeds, and particularly northern sea lions, responded to blasting by increasing activity and leaving a haulout. Blast-caused disturbances are believed to be triggered by responses to sounds that “scare” rather than injure animals. Observations of the effects of blasting on birds and pinnipeds were made during days when at least one of the three ranges was active. Because so few observations were made during blasting in Whirl Bay (4 days) and on Christopher Point (1 day), the value of any inference made from those data is limited. None of the data we collected suggested that blasting in Whirl Bay had any adverse effects on bird or pinniped behaviour in the study area. Blasting monitored on Christopher Point occurred at a time (20 February 2003) when few birds and pinnipeds were in the study area. Blasting on Bentinck Island was the most frequent form of blast-related, potential disturbances observed. Pre-disturbance pinniped activity levels did not differ significantly among the types of monitoring days. There were no significant differences in mean activity levels of pinnipeds during samples throughout the day when no disturbance stimulus was attributed to the observation when the Bentinck Island Range was active compared to days when the range was inactive. Of all pinniped species that occur at Race Rocks, northern elephant seals were the most tolerant of any forms of disturbance we observed. Blasts on Bentinck Island displacement. Pinnipeds, and particularly northern sea lions, responded to blasting by increasing activity and leaving a haulout. Blast-caused disturbances are believed to be triggered by responses to sounds that “scare” rather than injure animals. Observations of the effects of blasting on birds and pinnipeds were made during days when at least one of the three ranges was active. Because so few observations were made during blasting in Whirl Bay (4 days) and on Christopher Point (1 day), the value of any inference made from those data is limited. None of the data we collected suggested that blasting in Whirl Bay had any adverse effects on bird or pinniped behaviour in the study area. Blasting monitored on Christopher Point occurred at a time (20 February 2003) when few birds and pinnipeds were in the study area. Blasting on Bentinck Island was the most frequent form of blast-related, potential disturbances observed. Pre-disturbance pinniped activity levels did not differ significantly among the types of monitoring days. There were no significant differences in mean activity levels of pinnipeds during samples throughout the day when no disturbance stimulus was attributed to the observation when the Bentinck Island Range was active compared to days when the range was inactive. Of all pinniped species that occur at Race Rocks, northern elephant seals were the most tolerant of any forms of disturbance we observed. Blasts on Bentinck Island were the only disturbance to consistently cause a noticeable increase in harbour seal activity for those animals that were not displaced. Blasts on Bentinck Island caused the most noticeable increases in California sea lion activity. Blasts on Bentinck Island and unknown disturbance stimuli had noticeable effects on California sea lion displacement from land to water. Blasts on Bentinck Island caused the greatest increase in northern sea lion activity and ecotour boats also caused an increase in activity levels; particularly on days when the Bentinck Island Range was active. Blasts on Bentinck Island and unknown disturbance stimuli had the most noticeable effects on northern sea lion displacement from land to water. Blasts on Bentinck Island caused at least 1 northern sea lion to move to the water 90.7% of the time the species was present on a haulout. Boats and pedestrians also displaced these animals. Despite the northern sea lion’s sensitivity to blasting, displaced individuals typically began returning to the haulout within minutes or hours of the disturbance, indicating that they were not displaced from the study area or very far from it. Pedestrians displaced seals, sea lions and gulls from Great Race Rock. Pedestrian-caused disturbances typically involved: intentional clearing northern elephant seals off the boat launch; incidental displacement of harbour seals, incidental displacement of California sea lions, and to a lesser extent, northern sea lions; and incidental displacement of gulls. Overflights by raptors such as bald eagles were the most consistent (93.7% of events recorded) disturbance that caused some animals (in this case, primarily gulls) to take flight or enter the water. Very low numbers of aircraft passed over or near the monitored area, causing little or no apparent disturbance to wildlife. The Coast Guard helicopter might be an exception. Kayakers were rare in the monitored area. Boats operated by LBPC were observed regularly throughout the monitored period, and together with the LGL boat, were the only boats to regularly dock at Race Rocks. LBPC and LGL boats displaced modest numbers of birds and pinnipeds from the dock area during most arrivals and departure. Pleasure boats were observed throughout the monitored period, mainly in summer. Harbour seals, sea lions, and cormorants, were all displaced by pleasure boaters. Some poaching of fish and shellfish occurs by recreational fishermen and recreational scuba divers, respectively. Ecotour boats constituted the greatest amount of boat traffic in the monitored area, with peak visitation rates during the height of the summer tourist season. Daily numbers of ecotour boats ranged from 0 to 43, with as many as nine present in the study area at the same time. Some ecotour boats were observed to displace harbour seals, sea lions, cormorants, and gulls, but most caused no observable effects. The fact that Race Rocks provides highly suitable habitat for marine birds and pinnipeds is indisputable. However, determining the extent to which Race Rocks provides important or critical habitat for any given species is not so straightforward. Northern Sea Lion (COSEWIC, Special Concern; Conservation Data Centre, Red Listed) is the only species that could be reasonably expected to pose any local conservation concerns at Race Rocks at present. The black oystercatcher (COSEWIC, Not Listed; Conservation Data Centre, Yellow Listed) might become a concern in the future at Race Rocks due to the relatively low number of breeding pairs in the province. Marine birds and pinnipeds at Race Rocks are exposed to a number of different disturbance stimuli that alter normal behaviour patterns. The fact that human activities disturb wildlife does not in itself provide a basis to ban such activities. Indeed, if that were the case, no people or boats would be permitted in the Race Rocks Ecological Reserve without authorization. If disturbances have no consequences for the population, or even if the population consequences are sustainable, restricting human activities for the sake of preventing disturbance is likely to have negative social and other consequences that are out of proportion to the impacts that are being avoided or mitigated. By increasing animal activity and displacing animals from the land to the air and water, humans exert adverse effects on marine birds and pinnipeds at Race Rocks. However, no significant adverse effects stemming from single or cumulative disturbance types on the regional populations of any species of marine bird or pinniped at Race Rocks Ecological Reserve are expected to presently originate in, or immediately adjacent to, the study area. ACKNOWLEDGEMENTS
Many people assisted with this study. We especially thank Duane Freeman (Department of National Defence, CFB Esquimalt, Formation Environment) and Andrew Smith (Public Works and Government Services Canada) for their leadership and assistance in conducting this important research. Duane Freeman and Tracy Cornforth (Formation Environment) provided constructive reviews of draft of this report. Rae-Ann Shaw (Public Works and Government Services Canada) provided important administrative assistance. Duane Freeman and his department staff reviewed a draft of this report. PO Rob Cantwell, PO Chris MacDonald, and PO Oliver provided important logistic support concerning training activities on Bentinck Island and Whirl Bay. ESO Al Carter provided information concerning Christopher Point. Rik Simmons, Don McLaren, and Debbie McKinnon (Province of BC) assisted with research permitting. Captain Terry Weber and Vivian Skinner (Canadian Coast Guard) provided access to the light tower. Phil Emery (Canadian Coast Guard) coordinated a staged helicopter landing. Angus Matthews, Garry Fletcher, and Mike and Carol Slater (Pearson College) provided logistical support on Great Race Rock. Peter Olesiuk (Department of Fisheries and Oceans) provided some information on pinnipeds. Gary Searing of LGL provided important assistance with the study proposal and reviewed a draft of this report. Steve Johnson reviewed portions of a draft of this report. Dorothy Baker of LGL Limited proofed draft of this report. Mike Demarchi, Steve Johnson and Sonya Meier supervised field activities. Michael Bentley, Karen Truman, Lucia Ferreira, Jim Ferguson, Virgil Hawkes, Dave Robichaud, Jason Smith, Andrew Davis, and Philina English assisted with data collection. All photographs were taken by the senior author, except where noted. Suggested Citation: DEMARCHI, MW AND MD BENTLEY. 2004. Effects of natural and human-caused disturbances on marine birds and pinnipeds at Race Rocks, British Columbia. LGL Report EA1569. Prepared for Department of National Defence, Canadian Forces Base Esquimalt and Public Works and Government Services Canada. 103 p.
EXECUTIVE SUMMARY……………………………………………………………………………………………….i ACKNOWLEDGEMENTS……………………………………………………………………………………………..v CONTENTS………………………………………………………………………………………………………………vi 1 INTRODUCTION………………………………………………………………………………………………………1 4 METHODS………………………………………………………………………………………………………………18 4.1 ANALYTICAL LIMITATIONS………………………………………………………………………………………19 . 4.2 DATA ANALYSES………………………………………………………………………………………………….20 5 RESULTS………………………………………………………………………………………………………………..20 5.1 CENSUS DATA………………………………………………………………………………………………………23 5.1.1 Cormorants………………………………………………………………………………………………………….25 5.1.2 Bald Eagle…………………………………………………………………………………………………………..26 5.1.3 Gulls………………………………………………………………………………………………………………….26 5.1.4 Northern Elephant Seal………………………………………………………………………………………….27 5.1.5 Harbour Seal………………………………………………………………………………………………………28 5.1.6 California Sea Lion……………………………………………………………………………………………….28 5.1.7 Northern Sea Lion………………………………………………………………………………………………..29 5.2 NATURAL AND HUMAN-CAUSED DISTURBANCES……………………………………………………….30 5.2.1 Effects of Disturbance on Animal Abundance from Morning to Afternoon……………………………30 5.2.1.1 Cormorants……………………………………………………………………………………………………….30 5.2.1.2 Gulls……………………………………………………………………………………………………………….30 5.2.1.3 Northern Elephant Seal……………………………………………………………………………………….32 5.2.1.4 Harbour Seal…………………………………………………………………………………………………….32 5.2.1.5 California Sea Lion……………………………………………………………………………………………..33 5.2.1.6 Northern Sea Lion……………………………………………………………………………………………….35 5.2.2 Effects of Discrete Disturbance Events on Animal Abundance and Behaviour..…………………….37 5.2.2.1 Effects on Harbour Seals……………………………………………………………………………………..40 5.2.2.2 Effects on California Sea Lions………………………………………………………………………………41 5.2.2.3 Effects on Northern Sea Lions………………………………………………………………………………..43 5.2.2.4 Disturbance by Killer Whales…………………………………………………………………………………45 5.2.2.5 Disturbance by Raptors………………………………………………………………………………………..45 5.2.2.6 Disturbance by Pedestrians and Domestic Animals…………………………………………………….46 5.2.2.7 Disturbance by Aircraft…………………………………………………………………………………………48 5.2.2.8 Disturbance by Boats…………………………………………………………………………………………..49 5.2.2.9 Disturbance by Blasting………………………………………………………………………………………..53 6 DISCUSSION..……………………………………………………………………………………………………………54 6.1 RELEVANT LEGISLATION…………………………………………………………………………………………54 6.2 USE OF RACE ROCKS BY MARINE BIRDS AND PINNIPEDS…………………………………………..55 6.2.1 Birds………………………………………………………………………………………………………………….56 6.2.2 Northern Elephant Seal…………………………………………………………………………………………..56 6.2.3 Harbour Seal………………………………………………………………………………………………………..56 6.2.4 California Sea Lion…………………………………………………………………………………………………57 6.2.5 Northern Sea Lion………………………………………………………………………………………………….58 6.3 EFFECTS OF NATURAL AND HUMAN-CAUSED DISTURBANCE……………………………………….58 6.3.1 Birds…………………………………………………………………………………………………………………..61 6.3.2 Northern Elephant Seal……………………………………………………………………………………………63 6.3.3 Harbour Seal…………………………………………………………………………………………………………63 6.3.4 California Sea Lion…………………………………………………………………………………………………..65 6.3.5 Northern Sea Lion……………………………………………………………………………………………………65 7 LITERATURE CITED……………………………………………………………………………………………………..69 . 8 APPENDICES..………………………………………………………………………………………………………….74
viii LIST OF TABLES…………………………………………………………………………………………………………..Page Table 1. Dates and active range status in WQ during 52 monitoring sessions at Race Rocks……………21 Table 2. Distribution (percent) of all observations of common species and groups in the Race Rocks study area during morning and afternoon censuses from October 2002 through November 2003……………………………………………………………………………………………………………………………..24 Table 3. Summary of the presence and important seasonal uses (shaded cells) of Race Rocks made by species that commonly occur there……………………………………………………………………………………………………….24 Table 4. Results of logistic regression analyses to detect the effect of, tide, swell height, and Bentinck Island demolitions on the relative change in numbers of animals in the Race Rocks census area in the afternoon versus morning periods from October 2002 through November 2003……………………………………………………………………………………………………………………………..31 Table 5. Results of logistic regression analyses to detect the effect of number of projects in a run, tide height, swell height, air temperature, wind speed, wind direction, sea state, cloud cover, precipitation class, and visibility class on animal displacement during demolition runs on Bentinck Island from October 2002 through November 200…31 Table 6. Results of one-way ANOVA tests* of pre-discrete disturbance activity levels by type of monitoring day regarding military training range activities…………………………………………………………………………………………….37 Table 7. Results of t-Tests for differences between mean daily activity levels of pinniped based on samples when no discrete disturbance stimulus was attributed to the sample during days when Bentinck Island was active compared to days when no blasting occurred there (refer to Table 1 for dates included)……………………………………….37 Table 8. Percent of potential disturbance events that caused birds to fly or birds/pinnipeds to enter Table 9. Minimum, maximum, mean and standard deviation of the daily frequency of selected disturbance events as observed during 52 monitoring sessions at Race Rocks, BC spanning the period October 2002 through ix LIST OF FIGURES Page Figure 1. Map of southern Vancouver Island and eastern Juan de Fuca Strait………………………….3 Figure 2. Map of Sub-Areas within the study area……………………………………………………………………..4 Figure 3. Map of southern Vancouver Island and vicinity, showing Rocky Point, Race Rocks Ecological Reserve (within 20-fathom contour), and Military Training Area WQ (within circle)…………………………………………………………………………………………………………………………….6 Figure 4. Predicted tide heights at William Head during the study period………………………………………..22 Figure 5. Daily differences in predicted tide heights at William Head during the study period……………….22 Figure 6. Total numbers of cormorants on land in Race Rocks Ecological Reserve on each of 2 daily censuses (1=morning; 2=afternoon ) as observed from atop the light tower……………………………………………………25 Figure 7. Total numbers of bald eagles on land in Race Rocks Ecological Reserve on each of 2 daily censuses (1=morning; 2=afternoon ) as observed from atop the light tower……………………………………………………26 Figure 8. Total numbers of gulls on land in Race Rocks Ecological Reserve on each of 2 daily censuses (1=morning; 2=afternoon ) as observed from atop the light tower……………………………………………………………………27 Figure 9. Total numbers of northern elephant seals hauled out in Race Rocks Ecological Reserve on each of 2 daily censuses (1=morning; 2=afternoon ) as observed from atop the light tower. ……………………………………………………………………………………………………………………………………..27 Figure 10. Total numbers of harbour seals hauled out in Race Rocks Ecological Reserve on each of 2 daily censuses (1=morning; 2=afternoon ) as observed from atop the light tower…………………………………………………….28 Figure 11. Total numbers of California sea lions hauled out in Race Rocks Ecological Reserve on each of 2 daily censuses (1=morning; 2=afternoon ) as observed from atop the light tower ………………………………………29 Figure 12. Total numbers of northern sea lions hauled out in Race Rocks Ecological Reserve on each of 2 daily censuses (1=morning; 2=afternoon ) as observed from atop the light tower……………………………………………………..29 Figure 13. Boxplot summaries of daily changes in the abundance of gulls when Bentinck Island was inactive and when blasting occurred there, grouped by net change in swell condition in the afternoon versus morning peri ……32 Figure 14. Boxplot summaries of daily changes in the abundance of harbour seals when Bentinck Island was inactive and when blasting occurred there, grouped by net change in tide height in the afternoon versus morning peri…..33 Figure 15. Boxplot summaries of daily changes in the abundance of California sea lions when Bentinck Island was inactive and when blasting occurred there, grouped by net change in swell condition in the afternoon versus morning period…35 Figure 16. Boxplot summaries of daily changes in the abundance of Northern sea lions when Bentinck Island was inactive and when blasting occurred there, grouped by net change in swell condition in the afternoon versus morning period…36
Figure 17. Stacked line (cumulative total) chart of potential disturbance events (i.e., raptor, boat, pedestrian, and air traffic) during 52 monitoring sessions in the Race Rocks study area of from 6 October 2002 through 27 November 2003…………………………………………………………………………………………………………………..39 Figure 18. Number of blasts that occurred during each of the 52 monitoring sessions in the Race Rocks study area of from 6 October 2002 through 27 November 2003………………………………………………………………………….39 Figure 19. Activity levels of harbour seals at Race Rocks expressed as the mean values observed for each disturbance class on days when no blasting occurred (“No Range”), days when blasting occurred on Bentinck Island (“Bentinck”), and days when blasting occurred in Whirl Bay (“Whirl Bay”) only…………………………………………………………..40 Figure 20. Comparative changes in numbers of harbour seals in monitored sub-areas for selected potential disturbance types…………………………………………………………………………………………………………………………………41 Figure 21. Activity levels of California sea lions at Race Rocks expressed as the mean values observed for each disturbance class on days when no blasting occurred (“No Range”), days when blasting occurred on Bentinck Island (“Bentinck”), and days when blasting occurred in Whirl Bay (“Whirl Bay”) only……………………………………..42 Figure 22. Comparative changes in numbers of California sea lions in selected monitored areas for selected potential disturbance types………………………………………………………………………………………………………………….43 Figure 23. Activity levels of northern sea lions at Race Rocks expressed as the mean values observed for each disturbance class on days when no blasting occurred (“No Range”), days when blasting occurred on Bentinck Island (“Bentinck”), and days when blasting occurred in Whirl Bay (“Whirl Bay”) only………………………………………44 Figure 24. Comparative changes in numbers of northern sea lions in selected monitored areas for selected potential disturbance types………………………………………………………………………………………………………………….45 Figure 25. Relative distribution of Lester B. Pearson College boats observed in Race Rocks Ecological Reserve during monitoring sessions from October 2002 through November 2003……………………………………………………….50 Figure 26. Relative distribution of pleasure boats observed in Race Rocks Ecological Reserve during monitoring sessions from October 2002 through November 2003………………………………………………………………………………….51 Figure 27. Relative distribution of ecotour boats observed in Race Rocks Ecological Reserve during monitoring sessions from October 2002 through November 2003………………………………………………………………………………….53 Figure 28. Conceptual model of the hierarchical effects of exposing a wildlife species to a non- directly lethal visual or aural disturbance stimulus……………………………………………………………………………………………………….61
LIST OF PHOTOS Page Photo 1. Aerial photo of Great Race Rock as viewed from the northwest………………………………..5 Photo 2. Adult glaucous-winged gull nesting on a grassy area of Great Race Rock………………………….12 Photo 3. Subadult male northern elephant seal………………………………………………………………………..13 Photo 4. Mother-pup pairs of harbour seals are commonly observed at Race Rocks during………………..14 Photo 5. Harbour seals haul out in abundance on intertidal portions of the study area………………………14 Photo 6. California sea lions hauled-out on Great Race Rock………………………………………………………15 Photo 7. Northern sea lions hauled out on Sub-Area 2-5 of Race Rocks…………………………………………16 Photo 8. Killer whales, such as this lone male, were infrequently observed in the study area. 7 August 2003….17 Photo 9. Example of tidal effect on the area of exposed land available for birds and pinnipeds……………. 23 Photo 10. Portion of a feeding flock of primarily gulls and cormorants, located approximately 2 km southeast of Race Rocks……………………………………………………………………………………………………………………………25 Photo 11. Example of how tide height affected haulout availability for harbour seals, including during the peak of their pupping season………………………………………………………………………………………………………………..34 Photo 12. An example of typical pinniped responses to blasting…………………………………………………..36 Photo 13. Raptors such as this adult bald eagle frequently disturbed cormorants and gulls in the study area…46 Photo 14. Students and staff from Lester B. Pearson College were frequent visitors to Great Race Rock…47 Photo 15. Approximately 200 harbour seals moved quickly from the shore of eastern Great Race Rock into the water immediately after being apparently startled by a high-pressure power washer being operated by a resident of the island………………………………………………………………………………………………………………………………47 Photo 16. Two tourists wander through an active glaucous-winged gull nesting area (Sub-Area H) on Great Race Rock; causing disturbance and risking egg destruction by trampling………………………………………………………..48 Photo 17. Most aircraft overflights did not cause animals to leave the rocks for the water or air. ……………49 Photo 18. Pleasure boat near a pod of killer whales moving north through Race Passage…………………….52 Photo 19. Ecotour boat traffic was common throughout the year, but particularly during summer. ………….52
LIST OF APPENDICES Page Appendix 1. Legislation with direct or potential relevance to marine life at Race Rocks.. ……………74 Appendix 2. Data collected during monitoring sessions at Race Rocks…………………………………………..85 Appendix 3. Methods used for the analysis of data collected during animal censuses and activity sampling in the Race Rocks study area………………………………………………………………………………………………………………87 Appendix 4. Total numbers of pinnipeds, gulls, cormorants, and shorebirds in Race Rocks Ecological Reserve as counted from atop the light tower during each of the two daily censuses for the monitoring period 6 October 2002 through 27 November 2003……………………………………………………………………………………………………………..91 Appendix 5. Total numbers of birds in Race Rocks Ecological Reserve as counted from atop the light tower during each of the two daily censuses for the monitoring period 6 October 2002 through 27 November 2003……………………………………………………………………………………………………………………………….94 Appendix 6. Total number of potential disturbance events recorded in the monitored area during each monitoring day at Race Rocks, BC. ……………………………………………………………………………………………………………..99 Appendix 7. Sample sizes used to calculate mean activity rates (proportion of animals with heads up) of three pinniped species at Race Rocks, BC as a function of whether or not a demolition range (i.e., Bentinck Island, or Whirl Bay) was active and according to individual disturbance stimuli (primary) or lack thereof (none)…………………………101 Appendix 8. All dates and approximatea number of projects detonated on Bentinck Island from 11 July 2002 (the most recent blasting prior to the onset of this study) through 30 November 2003………………………………………102 Appendix 9. Number of ordnances detonated at Christopher Point Ordnance Disposal Range during the study period of October 2002 through November 2003 by date, ordnance type, and individual weight………………………….103
Race Rocks is a provincial ecological reserve and has been proposed as a federal marine protected area. The area supports a diverse range of marine algae, marine invertebrates, fish, marine birds, and pinnipeds (seals and sea lions). Marine birds use Race Rocks for breeding and non-breeding purposes. Pinnipeds are of particular relevance to this study because they are large, conspicuous animals that have been the focus of concerns about the effects of local human disturbance. Harbour seals breed and haul out at Race Rocks, and northern elephant seals, California sea lions, and northern sea lions haul out there. Cetaceans transit the area intermittently. A major portion of Race Rocks Ecological Reserve is contained within the Department of National Defence’s (DND) Military Training Area WQ; however no training activities actually occur within the Reserve. The effects of the demolition training and ordnance disposal activities in WQ were first studied by LGL Limited during 1997 and 1998 (Demarchi et al. 1998). Results of that study indicated that some pinnipeds at Race Rocks responded to ordinance explosions by increasing their activity levels and moving from haulouts to the water. It was also noted that other human uses in the study area (e.g., whale watching boats, pleasure boats, human activity on Great Race Rock, etc.) elicited similar reactions from birds and pinnipeds. The initial study (Demarchi et al. 1998) was confined to a limited portion of the year and only on days when military exercises involving explosions occurred. Observations of the behavioural effects of non-military disturbances on marine life were opportunistically collected, but that study was not designed to assess impacts from non-military activities. The present study was designed to monitor the effects of natural environmental processes; military explosions; and non- military, human-caused (anthropogenic) disturbances on marine birds and pinnipeds at Race Rocks during a 14-month period. The diversity of marine life at Race Rocks makes it a popular location for boaters, divers, recreational adventurers, students, and researchers. These activities have the potential to disturb marine life. In addition, the absence of substantial human settlements in the area facilitates the regular use of high explosives by DND. It is important to recognize that military exercises represent one type of many potential disturbances that occurs locally. Therefore, it is important to try to assess the response of marine birds and pinnipeds to explosions independent of other impacts and the potential impacts of explosions in addition to all other impacts (i.e., the cumulative impacts). 1.1 Study Objectives This research focused on pinnipeds (seals and sea lions). However, selected species of marine birds were also monitored. This research was conducted under Park Use Permit #VI0210066. The objectives were to:
2 LGL Limited
Marine birds and mammals at and near Race Rocks are subject to a number of different legislative acts and their corresponding regulations. A summary of relevant legislation is presented in Appendix 1. 3 STUDY AREA AND VICINITY 3.1 Race Rocks Ecological Reserve The study area is the exposed portion of Race Rocks Ecological Reserve, adjacent to Rocky Point on southern Vancouver Island (Figure 1; Figure 2). The Reserve is defined as the seabed and exposed land within the 20-fathom depth contour. Race Rocks is a complex composed of one island (Great Race Rock; 1.48 ha) and a number of smaller islets and reefs. Terrestrial vegetation occurs only on Great Race Rock, and consists of grasses and small forbs comprising both native and introduced species. Lester B. Pearson College of the Pacific (LBPC) operates several provincially owned buildings, including an ecoguardian (caretaker) residence, guest house, boat shed, tank room, crane shed, and diesel generator shed. Ancillary equipment operated by LBPC includes a concrete boat dock and launch, fixed crane, fuel pumping equipment, and diesel tanks. The Canadian Coast Guard leases a concrete helipad, light tower, and support infrastructure located on Great Race Rock (Photo 1). Great Race Rock was added to the Ecological Reserve in 2001. Race Rocks Ecological Reserve is in the eastern reaches of Juan de Fuca Strait in the Nanaimo Lowland Ecosection of the Eastern Vancouver Island Ecoregion of the Georgia Depression Ecoprovince (Demarchi et al. 1990). The climate of the study area is mild, being moderated by the Pacific Ocean. Tides are semidiurnal1 with strong diurnal inequality.2 Predicted values ranged from -0.11 to 3.06 m at William Head (located within 5 km north of Race Rocks) during the study period (Hopper 2002). Tidal flow through Race Passage can reach 7 knots. More comprehensive information on the biophysical features of Race Rocks Ecological Reserve can be found in Wright and Pringle (2001) and Province of BC (2002).  Figure 1 map of Southern Vancouver Island and Eastern Strait of Juan de Fuca
The Whirl Bay Underwater Demolition Range is used primarily by Fleet Diving Unit (Pacific) (FDU(P)) for underwater demolitions and ordnance testing using charges of C4 plastique3 ranging from 0.5 to 10 kg. The part of Whirl Bay that is used for demolitions is a shallow (<15 m) cove approximately 300 m across and 190 m from the entrance to the demolition beach. The substrate of the cove consists of basaltic bedrock overlain by clay, mud, silt, and sand with several patches of kelp scattered over the bottom. Shoreline habitats consist of basaltic rock formations and pebbly and sandy beaches.
In October 2002, a bubble curtain was deployed in Whirl Bay as a means of attenuating the shock pulse of underwater detonations, and thereby reducing the adverse effects on underwater marine life. Prior to the actual demolitions, several “Thunderflashes” are detonated to scare marine life away from the blast area. The demolition area is >2 km from the nearest haulout in Race Rocks and is separated from Race Rocks by Christopher Point. Bentinck Island (31 ha) is separated from Rocky Point by Eemdyk Passage—a shallow channel that supports an abundance of bull kelp. Harbour seals are common in Eemdyk Passage, but other pinnipeds have not been seen there (pers. obs.). The mid-section of Bentinck Island is a low-lying, treeless area of pebble beaches connecting three larger areas which support stands of mature Douglas fir. The Bentinck Island Demolition Range is used primarily by Canadian Forces Fleet School (Seamanship Division) for above-water beach-clearing and obstacle-creation exercises involving metal cutting and the displacement and demolition of rocks and logs. The range is licensed for a maximum individual charge size of 2.3 kg (CFB Esquimalt Range Standing Orders). Petty Officer (PO) B. Phillips (pers. comm. 1996) indicated that in the past, the range has been typically used for 56 days per year, but demolitions do not occur on all such days. “Project” is the term used to describe an individual demolition (e.g., timber cut, steel cut, beach clearing, etc.) involving a single explosive charge. “Run” is the term used to describe a set of projects that are simultaneously set up by different teams of trainees. As of 1998, projects in the same run are detonated at a minimum interval of 2 minutes. There was no minimum interval between projects prior to 1998. During a typical day on which the range is active, two to four runs of one to three projects each (i.e., 4-12 blasts per day) are conducted. A typical project consists of one to four slabs4 of C4. Demolition training is conducted on the central beaches of Bentinck Island, with a line-of-sight to Race Rocks. The nearest haulout used by seals and sea lions in the Race Rocks Reserve is approximately 1.2 km away. Surplus ordnance is disposed by way of high-order5 detonation at the Christopher Point Demolition (disposal) Area. Disposal activities are conducted on an as-required basis, and unlike the other ranges in WQ, activities on the Christopher Point Range are not tied to training schedules. Under federal authorization, the disposal area is licensed for a maximum single explosive charge size of 13.6 kg. Twelve such charges are permitted per day. However, as a means of mitigating public concerns about blast noise, a voluntary reduction6 in maximum charge size to 6.8 kg was adopted in 1987 (Explosives Safety Officer [ESO] A. Carter, pers. comm. 1997). Use of the range varies greatly among years, but anywhere from one to 12 high- order detonations on up to 25 days (7%) of the year is a reasonable approximation (ESO A. Carter, pers. comm. 1997). The disposal site is situated in a clearing characterized by Scotch broom and mowed grass. The range has a line-of-sight to Race Rocks. The nearest haulout used by seals and sea lions in Race Rocks Ecological Reserve is approximately 2.0 km away. 3.3 Marine Life The marine habitats of southern Vancouver Island support a diverse array of invertebrates, fish, birds, and mammals. The terrestrial and marine habitats near Rocky Point are important breeding areas, summering areas, wintering areas, migration corridors, or staging areas for approximately 200 species of birds (Campbell et al. 1990a, b; 1997; 2001). The most conspicuous mammals are the pinnipeds (seals and sea lions). The harbour seal (Phoca vitulina) is the only pinniped species that breeds in the study area. The abundance of California sea lions (Zalophus californianus) and northern sea lions7 (Eumetopias jubatus) is greatest outside the May-July breeding season. Northern elephant seals (Mirounga angustirostris) have occurred at Race Rocks in recent years. Single northern fur seals (Callorhinus ursinus) have been reported, but sightings of this species are very infrequent. Cetaceans such as killer whales (Orcinus orca) and gray whales (Eschrichtius robustus) are occasionally observed in or near the study area, but do not occur there with the same predictability as pinnipeds. 4 A slab of C4 weights 0.500 kg
3.3.1 Injury and Disturbance Ecotourism is a thriving venture both worldwide and on southern Vancouver Island. The tourism industry in Victoria is significant to the local economy. Local entrepreneurs have been quick to capitalize on a large population of tourists and residents willing to pay to see whales and other marine mammals such as sea lions. Obee (1998) presents a general discussion of the rapid growth of this business and the negative effects it can have on local marine life. Wildlife viewing by the pleasure-boating general public can also disturb wildlife. Tershy et al. (1997) describe how humans affected a reserve used by marine birds and pinnipeds. As observed by Demarchi et al. (1998), ecotourism and other human activities at Race Rocks are capable of disturbing birds and pinnipeds. In terms of the responses by individual animals, such disturbances are comparable to those caused by blasts. However, when taken in the perspective of an entire year, disturbances by boats and humans could out-weigh disturbances caused by explosions because the former disturbances are more frequent. Whereas DND activities occur infrequently during the course of a year, boats and other human-caused disturbances occur almost daily when weather conditions are suitable. Disturbances of birds and pinnipeds by boats and human activities on Race Rocks can be viewed as cumulative impacts on the species in question. As reported by Demarchi et al. (1998), blasting often coincided with the presence of ecotourists and pleasure boaters. As recreational boat traffic at Race Rocks increases, the likelihood of such events coinciding is expected to increase. Consequently, an increase in the number of complaints to DND regarding the effects of blasting activities on marine mammals can be expected, 9 LGL Limited (sentence missing in original copy??) regardless of the degree to which any observed disturbances were caused or compounded by the presence of the boat and its occupants 8. 3.3.2 Species Accounts The Committee on the Status of Endangered Wildlife in Canada (COSEWIC) tracks the status of flora and fauna in Canada. Listing categories applicable to the species presented in this section are defined as:
In BC, flora and fauna are assessed for concerns about their conservation by the provincial Conservation Data Centre (CDC). Listing categories are as follows:
The following accounts describe selected bird and mammal species that occur at Race Rocks. Current COSEWIC listings are followed by current CDC listings. 3.3.2.1 Brandt’s Cormorant (Not Listed; Red Listed) Brandt’s cormorants are uncommon to abundant throughout south-coastal BC during the year. Several small breeding colonies exist in BC, and in 1987 three nests with young were found at Race Rocks (Campbell et al. 1990a). They are much more abundant near southern Vancouver Island from August to April (Gates 2001) when numerous birds arrive from breeding areas along the west coast of the United States. Brandt’s cormorants roost on Race Rocks and forage in the surrounding waters during autumn through spring. 3.3.2.2 Double-crested Cormorant (Not at Risk; Blue Listed) Double-crested cormorants are common residents of southern Vancouver Island, breeding mainly on islands in the Strait of Georgia (Gates 2001, Campbell et al. 1990a). The breeding population has been decreasing in BC in the last two decades (Fraser et al. 1999; Chatwin et al. 2002). Double-crested cormorants commonly rest on the Race Rocks islets and feed in the waters of the Ecological Reserve and surrounding area. The species is not known to breed at Race Rocks.
Editors note: We have linked some of the following species to the appropriate reference in the racerocks.com Taxonomy Files. That was not part of the original report. 3.3.2.3 Pelagic Cormorant (pelagicus subspecies Not Listed; Red Listed – resplendens subspecies Not Listed; Yellow Listed) Two subspecies of pelagic cormorant occur in BC and both may occur at Race Rocks. The pelagicus subspecies nests north of Vancouver Island and in Alaska and is Red-listed due to a decline in numbers. It may occur at Race Rocks occasionally during the non-breeding season. The resplendens subspecies breeds in south-coastal BC including Race Rocks (Vermeer et al. 1989a). The number of pelagic cormorants nesting on Race Rocks varies from year to year with 120 counted by Vermeer et al. (1989a) in 1987 and 0 in 2000 (Chatwin et al. 2002). Pelagic cormorants use the rocks and islets of Race Rocks throughout the year for resting and the surrounding waters for feeding. 3.3.2.4 Bald Eagle (Not at Risk; Yellow listed) Bald eagles are fairly common on southern Vancouver Island from September to mid-May. During the summer months many of them move north to areas where salmon are spawning and are uncommon locally during that time. Bald eagles usually build their nests in large trees close to water. They breed near Race Rocks along the shore of Vancouver Island, but not within Race Rocks Ecological Reserve. Bald eagles use Race Rocks Ecological Reserve mainly as a resting and feeding area where they forage on fish and gulls. 3.3.2.5 Peregrine Falcon (anatum subspecies Threatened; Red Listed – pealei subspecies Special Concern; Blue Listed) Three subspecies of peregrine falcons occur in BC. Although all three probably occur at Race Rocks occasionally, the most likely and frequent is probably the Peale’s peregrine falcon. Peregrine falcons breed in small numbers throughout south-coastal BC. Peregrine falcons from other areas of the west coast migrate through and/or winter in the study area. Peregrine falcons hunt their main prey (other birds) frequently in Race Rocks Ecological Reserve. At times they rest or consume prey on the terrestrial portions of the Reserve, frequently perching on man-made structures on Great Race Rock or on higher portions of the rocky shorelines. 3.3.2.6 Black Oystercatcher (Not Listed; Yellow Listed) Black oystercatchers are common residents and breeders at rocky coastal shoreline areas of southern Vancouver Island (Gates 2001). Three pairs were counted on the islets of Race Rocks in 1987 (Vermeer et al. 1989b). It is reported by LBPC that up to six pairs nest on the islets (Race Rocks 2003). During the non-breeding season up to 40 or more birds aggregate at Race Rocks. In winter during daylight (high tide) hours they spend much of their time on Race Rocks resting and preening. 3.3.2.7 Black Turnstone (Not Listed; Yellow Listed) Black turnstones are common at marine shoreline habitats on southern Vancouver Island from August to mid-April (Gates 2001). They prefer rocky coastlines and are commonly seen on Race Rock islets feeding and resting. 3.3.2.8 Surfbird (Not Listed; Yellow Listed) Surfbirds are present in small numbers on the marine shoreline habitats of southern Vancouver Island from late July to April. They do not breed in the study area (Gates 2001). Small numbers feed and rest on Race Rocks during that time, with peak numbers in spring and fall during migration. 3.3.2.9 Rock Sandpiper (Not Listed; Yellow Listed) Race Rocks is one of the best places to see rock sandpipers in the Victoria area. This species is quite rare in the region occurring almost exclusively on the rocky shores of offshore islands and islets. Rock sandpipers are regular in small numbers on Race Rocks from late October to late May. They do not breed in the study area. The islets of Race Rocks Ecological Reserve are used for resting during high tide and feeding during lower tides. 3.3.2.10 Heerman’s Gull (Not Listed; Yellow Listed) Heerman’s gulls are common in south coastal BC from mid-July to the end of October when most of their population moves north along the Pacific coast from their Mexican breeding grounds. They are very rare at other times of the year and do not breed in BC (Gates 2001, Campbell et al. 1990b). Hundreds of Heerman’s gulls use the islets of Race Rocks for resting and the surrounding waters for feeding during their time in this area. 3.3.2.11 California Gull (Not Listed; Blue Listed) California gulls are common to abundant during their spring (March-April) and fall (July- October) migrations in the southern Vancouver Island area. They are quite rare at most other times of the year and do not breed in the study area (Gates 2001). They commonly feed in the water surrounding Race Rocks and rest on the islets during their stay in the area. 3.3.2.12 Herring Gull (Not Listed; Yellow Listed) Herring gulls are uncommon at southern Vancouver Island from September to April and rare during the rest of the year. This species is mainly an offshore gull in BC. Race Rocks is probably one of the better places to observe this species near shore and small numbers use the islets for resting and the surrounding waters for feeding mainly during the winter. 3.3.2.13 Thayer’s Gull (Not Listed; Yellow Listed) Thayer’s gulls are common winter visitors at southern Vancouver Island from about mid- September to March. They are not present or are very rare in the area from April to mid- September and do not breed in the area (Gates 2001). Very large numbers of Thayer’s gulls use Race Rocks during the fall and winter, resting on the islets and feeding in the surrounding waters. 3.3.2.14 Western Gull (Not Listed; Yellow Listed) Western gulls are uncommon to rare during most of the year near southern Vancouver Island (Gates 2001). This species nests along the Pacific coast of North America from Washington to California. At the northern edge of their range, hybridization with glaucous-winged gulls is frequent resulting in many hybrid birds that are impossible to classify to one species. Gulls that appear to be of pure western gull stock are uncommon to rare at Race Rocks Ecological Reserve throughout the year. They join the mixed-species gull flocks either resting on the islets or feeding in the surrounding water. Some of the gulls nesting at Race Rocks are probably hybrids. 3.3.2.15 Glaucous-winged Gull (Not Listed; Yellow Listed) Glaucous-winged gulls are the only species of gull nesting at Race Rocks (Photo 2) with up to 424 nests counted in 1989 (Vermeer et al. 1992). They are common all year throughout the region and their numbers have increased dramatically in the last two decades. Other than as a nesting colony, Race Rocks Ecological Reserve is used all year for resting on the islets and feeding in the surrounding water. 3.3.2.16 Pigeon Guillemot (Not Listed; Yellow Listed) Pigeon Guillemots are the only species of alcid that nests at Race Rocks. They are in the area year-round, but only use the land in Race Rocks during spring and summer. This migratory species resides in rocky coastal areas, and prefers to forage in shallow, inshore waters. Pigeon guillemots nest in rock crevices on the periphery of Great Race Rock. The first nesting record was in 1953 and published numbers of breeding pairs there range from 14 to 400 (Campbell et al. 1990b).  Photo 2. Adult glaucous-winged gull nesting on a grassy area of Great Race Rock. 25 May 2003. LGL Limited 13 |
3.3.2.17 Northern Elephant Seal (Not at Risk; Yellow Listed)
The northern elephant seal (Photo 3) is a member of the family Phocidae—the true seals. Although near extinction at the beginning of the 20th century, legal protection of the species and its habitat has allowed it to recover. In 1991 there was an estimated population of 127,000 animals (Stewart and Huber 1993). This species is highly migratory, breeding primarily on islands in northern Mexico and central California and moving north after the breeding season. After breeding, most animals stay far offshore in deep water. Males move over the continental shelf as far north as the Gulf of Alaska and Aleutian Islands, while females tend to move westward into the open ocean (Stewart and Huber 1993).
Northern elephant seals can haul out at any time of the year, but Stewart and Huber (1993) note three seasonal peaks in abundance at haulouts. The first is in winter during the combined pupping and breeding season. The second is in late April and early May when adult females and subadults come ashore to moult. The third is in October when non-pregnant females, pups, yearlings, and subadults come ashore to moult.
ED. NOTE: the following is now out of date since Elephant seals now breed and pup at Race Rocks
Photo 3. Subadult male northern elephant seal. Members of this species commonly hauled-out on and near the boat launch at Great Race Rock. They tolerated humans at very close distances, to the point of becoming a nuisance at times as they interfered with boat launchings and landings. This individual is moulting its brown fur, exposing its grey, scarred skin beneath. 26 June 2003.
Baird (1990) reported that northern elephant seals are sparsely, but widely distributed in British Columbian waters throughout the year and are usually seen singly. Race Rocks is one of the few spots in BC where elephant seals regularly haul out. The account by Cowan and Carl (1945) suggests that, at least up to the mid-20th century, northern elephant seals were not as common in BC as they are at present. Based on their size and general appearance, most animals using Race Rocks are adult females or subadults, although a few adult males also haul out there.
Photo 3. Subadult male northern elephant seal. Members of this species commonly hauled-out on and near the boat launch at Great Race Rock. They tolerated humans at very close distances, to the point of becoming a nuisance at times as they interfered with boat launchings and landings. This individual is moulting its brown fur, exposing its grey, scarred skin beneath. 26 June 2003.
Photo 4. Mother-pup pairs of harbour seals are commonly observed at Race Rocks during summer. The species is present at Race Rocks year-round. Sub-Area G; 17 July 2003.
Photo 5. Harbour seals haul out in abundance on intertidal portions of the study area. Sub-area F; 17 July 2003. LGL Limited 15
3.3.2.19 California Sea Lion (Not at Risk; Yellow Listed)
The California sea lion (Photo 6) is a member of the eared seal family, Otariidae. California sea lions move north into the study area from breeding colonies in Mexico and California after each summer breeding season, then return south in the late winter and spring. Peak abundance in BC is between September and May. Most of the animals in BC are adult and subadult males but females are known to occur. The number of California sea lions using British Columbian coastal waters has increased substantially during the last century, and in particular, since 1980 (Bigg 1988a). Bigg (1988a) reported that California sea lions were not present on Race Rocks prior to 1965. Records from 1971 (summarized in Bigg 1988a) indicate a maximum of approximately 30 animals at Race Rocks. Since then, numbers have increased to several hundred animals at times. P. Olesiuk (pers. comm. 2002) indicated that California sea lions are expanding their non- breeding range northward within BC, but that little is known of this expansion due to limited monitoring of pinnipeds.
In recent years there has been a continued northward expansion of the species on both the east and west coasts of Vancouver Island (P. Olesiuk, pers. comm. 2002). A few radio tags deployed on California sea lions in the early 1990s revealed that while in BC waters, California sea lions are very mobile and do not remain in the same area (haulout) for extended periods (P. Olesiuk pers. comm. 2002). In BC, California sea lions appear to readily and rapidly shift their distributions in response to the movements of their main prey, salmon and herring (P. Olesiuk pers. comm. 2002). A northward shift in schools of adult herring during the mid-winter pre- spawning period has resulted in a concomitant shift in California sea lions. For example, they no longer occur in the same abundance at Harmac (near Nanaimo) as in the past, but greater numbers are now seen near Hornby Island to the north (P. Olesiuk pers. comm. 2002).
Photo 6. California sea lions hauled-out on Great Race Rock. The vast majority of California sea lions at Race Rocks are adult and subadult males. October 2002; (Photo: M. Bentley).
3.3.2.20 Northern Sea Lion (Special Concern; Red Listed)
The northern sea lion (Photo 7) is a member of family Otariidae (eared seals). The breeding range of this species is from California, along the Pacific coast to Alaska and northeast Asia. Two stocks are recognized: the Western Stock which ranges from Russia to the Gulf of Alaska; and an Eastern Stock which ranges from southeast Alaska to California. In BC between 1912 and 1968, thousands of northern sea lions were killed in a campaign to reduce the perceived conflict between this species and commercial fishermen. A review of historic data (Bigg 1988b) indicated that control programs and commercial harvests conducted in BC during 1912-1967 eradicated one breeding area and reduced numbers on the remaining rookeries to about 25-30% of peak levels observed in the early 20th century, prior to any large-scale culls. Numbers of northern sea lions on Race Rocks appear to have rebounded since the control program ended (Bigg 1988b). Presently there is considerable concern about conservation of the western stock because of a dramatic, unexplained decline since 1970 (Trites and Donnelly 2003). Conversely, the Eastern Stock (the one which occurs at Race Rocks) has exhibited a modest increase during this period (Bigg 1988a; Calkins et al. 1999). Despite this increase, in November 2003 COSEWIC upgraded this species’ listing from “Not at Risk” to “Special Concern” because there are only three breeding locations in BC, the species is sensitive to human disturbance while on land, the threat of acute oil spills, and unexplained declines in other populations to the north and west of BC .
The closest rookeries to Race Rocks are on the Scott Islands off northern Vancouver Island (Bigg 1988b; Loughlin et al. 1984). Northern sea lions migrate into the study area where they spend a considerable amount of time hauled-out on traditional beaches, rocks, and islets. Bigg (1988b) identified Race Rocks as a haulout site used by northern sea lions during their nonbreeding season, with peak abundance occurring during September through May. All sexes and age-classes (except newborn pups) of northern sea lions occur on Race Rocks.
Photo 7. Northern sea lions hauled out on Sub-Area 2-5 of Race Rocks. That area was commonly used by both sexes and all age classes. Photo date: 20 November 2003.
3.3.2.21 Killer Whale (Northeast Pacific Southern Resident population: Endangered, Red Listed – Northeast Pacific Transient population: Threatened, Red Listed) Killer whales (Photo 8) are large members of the family Delphinidae that occur in arctic, temperate, and tropical waters of the world’s oceans. Two different populations occur in and near the study area: residents (which typically forage on fish—namely salmon) and transients (which typically forage on pinnipeds). The terms resident and transient do not accurately denote the movement patterns of each population (references in Baird 2001b) and members of either population can occur in the study area at any time of the year. They are infrequent visitors to Race Rocks Ecological Reserve, seldom spending more than a few minutes in it when they do occur there (this study). Baird and Dill (1994, cited in Calambokidis and Baird 1994) reported that killer whales take “large numbers’ of harbour seals at Race Rocks, but such behaviour was never observed during the present study or that by Demarchi et al. (1998)
. Since 1960, the Southern Resident population of about 96 in 1967, declined to a low of 67 in 1971, then rose to about 100 individuals in 1995 (Baird 2001b). By 2001 the population had declined to 789, qualifying it as an endangered and “depleted stock” under the U.S. Marine Mammal Protection Act (Krahn et al. 2002). Much less is known of the local transient population.
Photo 8. Killer whales, such as this lone male, were infrequently observed in the study area. 7 August 2003.
9 The 2003 population estimate by the Washington-based Center for Whale Research
(http://www.whaleresearch.com/thecenter/southern.html) was 83.
The methodology employed in this study was based on that used during a similar study conducted in 1997 and 1998 (Demarchi et al. 1998). Race Rocks was accessed by an inflatable boat launched from Rocky Point. Monitoring days were selected to represent a sample of weekday and weekend conditions. Two or three observers recorded data in four different Microsoft Access 2002 databases using a hand-held Comapq iPAQ computer running Visual CE v6.1. Binoculars (8-10x) and tripod-mounted spotting scopes (20-60x) were used to assist with animal identification. In addition to the information presented below, additional information on data collection is presented in Appendix 2.
The first database concerned weather. Weather conditions were measured using on-site meteorological equipment (windspeed in knots and direction in degrees off true north) operated by the Coast Guard or by visual estimates (all others). As animal responses to disturbance may vary with time of day, cloud cover, wind speed, wind direction, wave height, swell condition, and tide height, weather parameters were measured in the morning and at the end of the day, and whenever notable changes in conditions occurred throughout the day. Tidal data were obtained for William Head (123° 32.0′ W, 48° 20.0′ N) using the computer program WXtide32 v2.7 (Hopper 2002). William Head is within 5 km to the north of Race Rocks.
The second database contained counts of bird and pinniped species in the study area. Those data provided information on how numbers of animals in the study area changed during daily and seasonal timescales. Birds and pinnipeds were censused twice (morning and afternoon). Only animals that were supported by terrestrial features (i.e., islands, islets, rocks, man-made structures, etc.) within one of the sub-areas (see Figure 2) were counted because of the difficulties in seeing animals in the water or counting birds in the air. Further, only animals visible from the tower were counted. Some animals were hidden from view, but in our opinion, based on our familiarity with the study area viewed from different boat-based vantages, the vast majority (>90%) of individuals were visible from the tower. Densely crowded pinnipeds also obscured the view of some animals. Considering these visibility biases, counts were likely lower than the actual number of animals within the Reserve.
The third database involved sweep counts of the numbers and behaviours of animals in selected sub-areas. These data facilitated an assessment of the effects of disturbance on bird and on pinniped behaviour and numbers by facilitating comparisons between pre- and post-disturbance conditions. These counts were made approximately every 30-60 minutes during the observation period, together with additional counts made immediately prior to, and within a few minutes following, blasting or the closest approach by people, boats, or aircraft. Two visible measures of disturbance are: 1) the change in body position (i.e., activity level; head-down or head-up of pinnipeds10), and 2) the change in numbers of pinnipeds on the haulouts and birds on hard surfaces. During samples of activity levels, we noted whether a disturbance stimulus was present or had occurred (e.g., if an ecotour boat was situated such that the passengers were focusing on the animals in the selected sub-area; or if a blast had just occurred). Multiple stimuli were recorded if they occurred simultaneously. Observations on the visible effects (or lack thereof) of a given stimulus were also noted as comments for each record.
10 It is acknowledged that sea lions sometimes rest in a head-up position, but in our experience at Race Rocks, the proportion of such animals is in the vast minority.
The fourth database tracked potential disturbance events. Because the nature of disturbances from sources other than blasting by DND were unpredictable both spatially and temporally, it was important to track such disturbances in the vicinity of marine animals. To that end, a 250 m by 250 m grid was superimposed on a map of the study area. Grid cells entered by each disturbance stimuli were recorded, as well as the time at which the disturbance entered and left the study area. Cells were recorded a maximum of one time per individual disturbance factor even if the factor temporarily left then re-entered the same cell.
Field sampling began 6 October 2002 and ended 27 November 2003. Where possible, days were scheduled to coincide with explosive training or demolition activities by DND. The dates and exact timing of explosions were coordinated with DND personnel. Up-to-the-minute reports on blast activities were monitored via VHF radio or cellular phone. “Non-training” days were scheduled to document responses to other sources of disturbance such as whale watching tours, pleasure craft, recreational dive boats, aircraft, and other types of human disturbance.
4.1 Analytical Limitations
Data analyses are complicated by several factors with implications for the application of statistical inference to the study’s results:
4.2 Data Analyses
Detailed descriptions of analyses based on census and activity sample data are presented in Appendix 3.
During the period 6 October 2002 through 27 November 2003, 52 monitoring sessions were conducted (Table 1). With the exception of two full days and one partial day when fog precluded accurate counts, monitoring was conducted as planned. On two other occasions, the trip to Race Rocks was cancelled due to extreme weather conditions. A wide range of weather conditions occurred during monitoring sessions, from sunny and clear to gale- and storm-force winds and rain storms. Observations were made under a wide range of tide heights and swell conditions.
Although much of the land in the Race Rocks complex is exposed at even the highest tides, the amount of exposed land available for resting birds and pinnipeds varied considerably as a function of tide height. Note that no attempt was made to quantify the total area available for resting at any given time. A strong seasonal pattern was observed for tide heights and daily timing, both as observed in the field and as calculated (Hopper 2002). The highest tides were observed during monitoring sessions in November through March (Figure 4). Storms were also more common at that time of year, causing swells and wind-waves that further decreased the availability of resting areas or shortened the duration intertidal areas were exposed during the day (Photo 9). The November-March period was also characterized by a tendency for tides in the late afternoon (near the time when the second daily census was conducted) to be lower than those in the morning (when the first daily census was conducted; Figure 5). The remainder of the year followed the opposite pattern. Tidal variation measured on an hourly scale was sufficient to strongly affect the availability of land for resting birds and pinnipeds—especially harbour seals. Other pinnipeds were not so visibly affected.
Proceed to PART 2
The following are reports done in later years :
MONITORING DEMOLITION TRAINING IMPACTS IN MILITARY TRAINING AREA WQ ON SEA LIONS IN THE RACE ROCKS ECOLOGICAL RESERVE, BRITISH COLUMBIA lgl2010progreport
PROGRESS REPORT #1 REVISED
LGL, Dec 8, 2010
EFFECTIVENESS OF A FIVE-MINUTE DEMOLITION INTERVAL TO MITIGATE BLASTING NOISE IMPACTS IN MILITARY TRAINING AREA WQ ON SEA LIONS IN THE RACE ROCKS ECOLOGICAL RESERVE, BRITISH COLUMBIA,
LGL, Mar 2010. 5mineffective
TEMPORAL SPACING OF DEMOLITIONS TO MITIGATE DEMOLITION TRAINING IMPACTS IN MILITARY TRAINING AREA WQ ON SEA LIONS IN THE RACE ROCKS ECOLOGICAL RESERVE, BRITISH COLUMBIA
LGL, Mar 23 2009 bentinck2089report
