resources of concern: Dungeness and rock crabs, pandalid shrimp, and sea cucumbers. Generally, Dungeness crab were scarce, rock crab (especially the.
FRI-UW-881 8 October 1988
FISHERIES RESEARCH INSTITUTE School of Fisheries University of Washington Seattle, WA 98195
PUGET SOUND DREDGE DISPOSAL ANALYSIS (PSDDA) DISPOSAL SITE INVESTIGATIONS: PHASE II TRAWL STUDIES IN NORTH
AND SOUTH PUGET SOUND Invertebrate Resource Assessments by Paul A. Dinnel, David A. Armstrong, Robert R. Lauth, and Karen Larsen
FINAL REPORT to WASHINGTON SEA GRANT AND U.S. ARMY CORPS OF ENGINEERS
Approved
—
Submitted____________________
_______________________________ Director
ABSTRACT The multi-agency Puget Sound Dredge Disposal Analysis Program has been delegated the task of evaluating, selecting, monitoring and managing sites within the inland waters of Washington State for long-term, unconfined disposal of un contaminated dredged materials. The Disposal Site Work Group of PSDDA was assigned the responsibility of selecting unconfined, open water disposal sites in Puget Sound based on nineteen selection factors covering physical parameters, human uses, historical biological ~resource data and site-specific trawl investigations. This document is one of two final technical reports detailing the results of the site-specific trawl surveys for Phase II PSDDA disposal sites located in North and South Puget Sound (the results of Phase I (Central Puget Sound sites) trawl surveys can be found in Dinnel et al. (1986)). The results of invertebrate resource assessments using a 3-m beam trawl are contained in this report. Results of the bottomfish investigations using a 7.6-rn otter trawl are contained in a parallel report by Donnelly et al. (1988). Phase II trawl surveys were conducted in the Nisqually Delta area of South Puget Sound and in Bellingham Bay, North Puget Sound. Trawling was conducted seasonally in and around two “non-dispersive” Zones of Siting Feasibility (ZSFs) in each area. Additionally, winter and summer trawling was also conducted in and around four tentative “dispersive” ZSFs, one located south of Point Roberts in the Strait of Georgia, one in Rosario Strait and two in the Strait of Juan de Fuca (one site each near Port Townsend and Port Angeles). The beam trawl survey in the Nisqually area identified the following invertebrate resources of concern: Dungeness and rock crabs, pandalid shrimp, and sea cucumbers. Generally, Dungeness crab were scarce, rock crab (especially the purple crab, Cancer gracilis) were abundant, pandalid shrimp sparse, and sea cucumbers (Parastichopus californicus) plentiful. Of the two Nisqually ZSFs, the eastern ZSF (ZSF #2 near Ketron Island) contained fewer invertebrate resources, all of which were relatively scarce compared to the Nisqually region in general. Beam trawling in Bellingham Bay identified the following invertebrate resources of concern: Dungeness and rock crabs, pandalid shrimp, sea cucumbers, and the large pink nudibranch, Tritonia diomedea, which is used as a neurophysiological research tool. Dungeness crab were more abundant than rock crab in Bellingham Bay. Several species of pandalid shrimp were abundant and served as the basis of a small commercial and sport fishery. Sea cucumbers were scarce and Tritonia were in low to moderate densities. Within the two proposed ZSFs, Dungeness crab and Tritonia densities were moderate and pandalid shrimp densities were gene rally high. On the basis of resource densities, neither ZSF could be recommended over the other. Catches of invertebrate resources in the dispersive Strait of Georgia ZSF were small, being limited to a few shrimp, scallops and sea urchins. Catches in Rosario Strait consisted of moderate numbers of pink scallops and sea urchins and low numbers of pandalid shrimp. Abundances of these resources were highest in the southern half of Rosario Strait. Invertebrate resources were similar in the dispersive Juan de Fuca ZSFs near Port Townsend and Port Angeles and consisted primarily of pandalid shrimp, pink scallops and sea urchins. Pink scallops and sea urchins were generally in high
abundance in each ZSF, while pandalid shrimp (mostly juveniles of several spe cies) were especially abundant during the October sampling period. Additional work will be required to identify sites with low resource densities in the Strait of Juan de Fuca.
TABLE OF CONTENTS Page
LIST OF FIGURES LISTOFTABLES LIST OF APPENDIX TABLES LIST OF ABBREVIATIONS, ACRONYMS AND SYMBOLS ACKNOWLEDGMENTS INTRODUCTION ME11-IODS General Gear Sample Sites Quality Assurance/Quality Control (QAIQC) Data Analyses RESULTS Nisqually Bellingham Bay Strait. of Georgia Rosario Strait Port Townsend Port Angeles DISCUSSION AND CONCLUSIONS Nisqually Region Bellingham Bay Strait of Georgia Rosario Strait Port Townsend Port Angeles LITERATURE CITED
I I
I vii vii viii Ix 1 2 2 2 3 5 5 6 6 10 15 17 18 19 21 21 23 24 24 25 25 26
~
LIST OF FIGURES Figure 1. Map of Puget Sound showing the PSDDA II sampling locations 2. Diagram of the 3-m beam trawl used to sample invertebrate resources in Puget Sound 3. Diagram of the rock dredge used for sampling in Rosarlo Strait and a few stations in the Strait of Georgia 4. Map of the Nisqually region of south Puget Sound showing the location of Zones of Siting Feasibility 2 and 3 and the stations sampled by beam trawl in and around the ZSFs in October 1987 5. Map of Bellingham Bay showing the preliminary locations of two Zones of Siting Feasibility and the locations sampled by beam trawl in October 1987 6. Map of the Point Roberts/southern Strait of Georgia area showing the preliminary location of a dispersive Zone of Siting Feasibility and the station locations sampled by both beam and otter trawis in October 1987 7. Map of Rosario Strait showing the preliminary location of a dispersive Zone of Siting Feasibility and the stations sampled by rock dredge in October 1987 8. Map of the Port Townsend portion of the Strait of Juan de Fuca showing the preliminary location of a Zone of Siting Feasibility and the stations sampled by beam and otter trawls in October 1987 9. Map of the Port Angeles portion of the Strait of Juan de Fuca showing the preliminary location of a Zone of Siting Feasibility and the stations sampled by beam and otter trawis in October 1987 10. Maps of the Nisqually region showing the densities of Dungeness crab as estimated from beam trawl catches in February, May, July and October1987 11. Summary of the estimated average densities of Cancer and tanner crabs by area, by season and by species based on the beam trawl catches 12. Summary of Dungeness crab depth distribution, size frequency, shell condition, sex composition, female repro ductive condition and egg age in the Nisqually region during four seasons of 1987 13. Summary of Cancer productus depth distribution, size frequency, sex composition, female reproductive condition and egg age in the Nisqually region during four seasons of 1987 III
Page 29 30 31
32 33
34 35
36
38 39
40
41
Figure 14. Summary of Cancer grad/is depth distribution, size frequency, sex composition, female reproductive condition and egg age in the Nisqually region during four seasons of 1987 15. Maps of the Nisqually region showing the densities of com mercial pandalid shrimp as estimated from beam trawl catches in February, May, July and October 1987 16. Summary of estimated average densities of pandalid shrimp by area, by season and by species based on the beam trawl catches 17. Size frequency distributions for spot prawn, caught by both beam and otter trawls combined by area and by season for 1987 18. Si7e frequency distributions for sidestripe shrimp, Pandalus dispar, caught by both beam and otter trawls combined by area and by season for 1987 19. Size frequency distributions for coonstripe shrimp, Pandalus danae, caught by both beam and otter trawls combined by area and by season for 1987 20. Size frequency distributions for the pink shrimp, Pandalus jordani, caught by both beam and otter trawis combined by area and by season in 1987 21. Size frequency distributions for the pink shrimp, Pandalus borealis, caught by both beam and otter trawis combined by area and by season in 1987 22. Size frequency distributions for Pandalus goniurus caught by both beam and otter trawis combined by area and by season in 1987 23. Size frequency distributions for humpback shrimp, Pandalus hypsinotus, caught by both beam and otter trawis combined by area and by season in 1987 24. Selected shrimp reproductive conditions by area, by season and by species 25. Maps of the Nisqually region showing sea cucumber densities as estimated from beam trawl catches in February, May, July and October 1987 26. Estimated average densities of various invertebrate species caught by beam trawl in 1987 by area, by season and by faunal group 27. Comparison of average beam trawl catches by species and by season between Nisqually ZSF 2 and ZSF 3
iv
Page 42 43 44 45 46 47 48 49 50 51 52 53 54 55
Figure 28. Comparison of average otter trawl catches by species and by season between Nisqually ZSF 2 and ZSF 3 29. Maps of Bellingham Bay showing Dungeness crab densities as estimated from beam trawl catches in February, May, July and October 1987 30. Summary of Dungeness crab depth distribution, size frequency, shell condition, sex composition, female reproductive condition and egg age in Bellingham Bay during four seasons of 1987 31. Summary of Cancer productus depth distribution, size frequency, sex composition, female reproductive condition and egg age in Bellingham Bay during four seasons of 1987 32. Summary of Cancer gracilis depth distribution, size frequen cy, sex composition, female reproductive condition and egg age in Bellingham Bay during four seasons in 1987 33. Summary of tanner crab, Chionoecetes bairdi, depth distribu tion, size frequency and sex composition in Bellingham Bay during four seasons of 1987 34. Maps of Bellingham Bay showing the densities of commercial pandalid shrimp as estimatedfrom beam trawl catches in February, May, July and October 1987 35. Maps of BeNingham Bay showing densities of the nudibranch Tritonia diomedea as estimated from beam trawl catches in February, May, July and October 1987 36. Maps of Bellingham Bay showing densities of the starfish, Luidea foiolata, as estimated from beam trawl catches in February, May, July and October 1987 37. Comparison of average beam trawl catches by species and by season in the North and South ZSFs in Bellingham Bay 38. Comparison of average otter trawl catches by species and by season between the North and South ZSFs in Bellingham Bay 39. Maps of the southern Strait of Georgia area showing densities of Dungeness crab, commercial pandalid shrimp, scallops and sea urchins as estimated from beam trawl catches in April 1987 40. Maps of the southern Strait of Georgia area showing the densi ties of Dungeness crab, commercial pandaild shrimp, scallops and sea urchins as estimated from beam trawl catches in October1987 41. Summary of Dungeness crab depth distribution, size frequency, shell condition, sex composition, female reproductive condition and egg age in the Strait of Georgia during four seasons of 1987
V
Page 56 57 58 59 60 61 62 63 64 65 66
67
68 69
Figure 42. Maps of Rosario Strait showing the number of commercial pandalid shrimp, pink scallops and sea urchins caught per 0.1 nautical mile by the rock dredge in April 1987 43. Maps of the Rosarlo Strait showing the number of commercial pandalid shrimp, pink scallops and sea urchins caught per 0.1 nautical mile by the rock dredge in October 1987 44. Maps of the Port Townsend region of the Strait of Juan de Fuca showing the densities of commercial pandalid shrimp, pink scallops and sea urchins as estimated from otter trawl catches in April1987 45. Maps of the Port Townsend region of the Strait of Juan de Fuca showing the densities of commercial pandalid shrimp, pink scallops and sea urchins as estimated from beam trawl catches in October1987 46. Maps of the Port Angeles region of the Strait of Juan de Fuca showing the densities of commercial pandalid shrimp, pink scallops and sea urchins as estimated from beam trawl catches in April1987 47. Maps of the Port Angeles region of the Strait of Juan de Fuca showing densities of commercial pandalid shrimp, pink scallops and sea urchins as estimated from beam trawl catches in October 1987
vi
Page 70 71
72
73
75
LIST OF TABLES Table 1. Summary of the average density (all stations and seasons combined) of major biological resources caught within the two Nisqually Zones of Siting Feasibility and at all stations combined 2. Summary of the average density (all stations and seasons combined) of major biological resources caught within the Bellingham Bay Zones of Siting Feasibility and at all stations combined
Page
14
LIST OF APPENDIX TABLES Table 1. Summary of the Nisqually area station location data 2. Summary of the Bellingham Bay station location data 3. Summary of the Point Roberts Dispersive Site station location data 4. Summary of the Rosario Strait Dispersive Site station location data 5. Summary of the Port Townsend Dispersive Site station location data 6. Summary of the Port Angeles Dispersive Site station location data 7. Estimated densities of invertebrate resources in and around each of the PSDDA Phase II proposed disposal areas as calculated from beam trawl catches 8. Estimated densities of invertebrate resources in and around each of the PSDDA Phase Il proposed disposal areas as calculated from otter trawl catches
vii
Page 77 80 82 83 84 85 86 90
LIST OF ABBREVIATIONS, ACRONYMS AND SYMBOLS CL CW DSWG PSDDA QAJQC UW YQY ZSF cm ha m mm MLLW NM >
carapace length carapace width Disposal Site Work Group Puget Sound Dredge Disposal Analysis Quality Assurance/Quality Control University of Washington Young-of-the-year Zone of Siting Feasibility centimeter hectare meters millimeters mean lower low water nautical mile greater than less than greater than or equal to less than or equal to approximately
viii
ACKNOWLEDGMENTS This work was supported by the Washington Sea Grant Program in cooperation with the Seattle District, U.S. Army Corps of Engineers. We appreciate the valuable assistance of Louie Echols and Alan Kreckel, Washington Sea Grant Program; Frank Urabeck, David Kendall and Steve Martin of the U.S. Army Corps of Engineers; and members of the PSDDA Disposal Site Work Group. All trawl work was conducted on board the R.V. Kittiwake skippered by Charles Eaton. Assistance in the field was provided by Russ McMillan, Tom Wainwright, Jan Armstrong, Ann Shaffer, Elliott Menashe, Brett Dumbauld, Anthony Whiley, Jay Orr and Yunbing Shi of the University of Washington; Justine Smith of the U.S. Army Corps of Engineers; Paula Ehlers of the Washington Department of Ecology; Gary Davis of the Washington Department of Fisheries; Jim Humphreys of Washington Sea Grant; and Karen Keeley and Heather Stout. Maxine Davis, Marcus Duke and Tom Quinn provided assistance with report preparation and editing.
ix
PUGET SOUND DREDGE DISPOSAL ANALYSIS (PSDDA) DISPOSAL SITE INVESTIGATIONS: PHASE II TRAWL STUDIES IN NORTH AND SOUTH PUGET SOUND Invertebrate Resource Assessments INTRODUCTION In January 1986, the Disposal Site Work Group (DSWG) of the Puget Sound Dredge Disposal Analysis (PSDDA) team selected preliminary preferred and alternative sites for the unconfined disposal of dredged materials in the main basin of Puget Sound (Phase I area). Initial disposal sites were selected based on information gathered from limited field studies conducted within the Zones of Siting Feasibility (ZSFs) and existing information from each ZSF. Selection of the final preferred disposal sites required more detailed evaluations of important physical factors and biological resources in and around the identified sites. Hence, trawl surveys of each of the proposed sites were conducted on a seasonal basis in 1986. These trawl data (Dinnel et al. 1986a), which provided spatial, temporal, density and life cycle information on important demersal invertebrate and epibenthic fishery resources, were used to help select final disposal sites that would least impact these resources. A similar siting process (Phase II) was initiated in late 1986 to select another group of disposal sites in the north and south areas of Puget Sound. Once again, seasonal trawl surveys were conducted in 1987 in and around two sites in each area designated as “non-dispersive” (near Nisqually Delta and Bellingham Bay) and four sites designated “dispersive” (near Point Roberts in Georgia Strait, Rosario Strait, and two sites near Port Angeles and Port Townsend in the Strait of Juan de Fuca; Figure 1).
2
This report describes the findings of the trawling studies conducted in and around the Phase II disposal sites during February, April-May, July and October 1987. The findings of the beam trawl surveys, which primarily focused on demer sal invertebrate resources, are summarized. A related report (Don~elly et al. 1988) describes the findings of the otter trawl surveys for these same areas. The otter trawl primarily targeted bottomfish resources but also provided some information on invertebrates. Additionally, a rock dredge was used in Rosario Strait owing to the very rocky bottom. The fish and invertebrate data obtained from the rock dredge are summarized in their respective reports.
METHODS
General All trawllng was conducted from the 16-rn research vessel Kittiwake. The otter trawl is described in Donnelly et al. (1988). Descriptions of the beam trawl and rock dredge follow below. In addition to trawling, surface and bottom water samples were collected by Niskin Sampler and measured for temperature, salinity and dissolved oxygen. These data are summarized in Donnelly et al. 1988. Trawl cruises were conducted on the following dates: 9 Feb-i March (non-dispersive sites only); 6-20 April (dispersive sites only); 6-13 May (non-dispersive sites); 8-24 July (non-dispersive sites); and 12-31 Oct (all sites). Gear Beam trawl. Demersal invertebrate fauna were sampled with a 3-rn beam trawl (Figure 2; Gunderson and Ellis 1986) previously used elsewhere in Puget Sound (Armstrong et at. 1987; Dinnel et at. 1985a, 1985b, 1986a, 1986b, 1987, 1988; Weitkamp et at. 1986). The beam trawl was towed approximately 232 meters (1/8 nautical mile (NM)) at a target ground speed of 2.5 km/hr (1.4 knots), which yielded
3
an area swept by the net (opening
=
2.3 m) of 534 m2. All crabs caught in the
trawls were measured for carapace width (CW), sexed, assessed for molt condition (degree of shell softness) and reproductive condition (females with or without eggs), and returned to the water. Catches of shrimp were preserved for later pro cessing in the laboratory, where all pandalid shrimp were identified and measured for carapace length (CL). Other demersal resources such as scallops, sea cucum bers, sea urchins, mussels and starfish were counted and returned to the water. Rock dredge. A rock dredge (86-cm wide x 38-cm high; Figure 3) was used to sample Rosario Strait and a few stations in the Strait of Georgia owing to the pres ence of rock and/or cobble on the bottom. The dredge was towed approximately 185 m (0.1 NM) unless obstacles necessitated a shorter distance. The large mesh of the rock dredge bag was lined with a beam trawl cod-end liner (5 mm mesh). The catches made with the rock dredge are considered qualitative since sampling efficiency is unknown and probably quite variable depending on bottom type. All animals caught in the rock dredge were processed as noted above for the beam trawl.
Sample Sites Beam trawl sample sites in the Nisqually area consisted of six stations in each ZSF (ZSF 2 and 3) and stations at selected depths (typically 10, 20, 40, 60 and 80 m) along five arbitrarily chosen transects in the Nisqually Delta/Anderson Island area (Figure 4). Four additional stations (A-D) were also added to provide better coverage in the deep-water areas between some of the transects. Otter trawl stations were a subset of the beam trawl stations and included all of the ZSF 2 and ZSF 3 stations. Bellingham Bay sampling stations were selected to give general coverage to the entire bay, since the selected ZSFs in this location were tentative. Stations
4
stratified by depth (10, 15, 20, 25 and 30 m) were established along four transects and an additional 10 stations (A-J) were randomly chosen in the deeper portion of Bellingham Bay (the most probable area for location of a disposal site; Figure 5). Otter trawl stations consisted of the randomly chosen stations (A-J) and a subset of the beam trawl transect stations. Sampling stations in the Point Roberts dispersive ZSF area included five stations (1-5) within the preliminary ZSF boundary, one station to the north (6) and one station to the south (7) of the ZSF; four stations (8-1 1) were selected for data continuity since these same stations were sampled by beam trawl in 1985-1 986 as part of a University of Washington/Sea Grant project (Dinnel, unpublished data). All 11 stations in this area were sampled with both the beam and otter trawls except Stations 5 and 7, which were sampled with the rock dredge owing to a rocky bottom. Beam trawl and otter trawl sampling was originally planned for six stations in Rosario Strait. However, since initial sampling with the beam trawl showed that the bottom was rocky (demolished nets and chains), the rock dredge was used and the number of stations increased to 11 to provide better spatial coverage (Figure 7). Sample locations in and around the Port Townsend ZSF included four stations (1-4) inside the ZSF boundaries, one station to the northeast (5) and one station to the southeast (6; Figure 8). Al! six stations were scheduled to be sampled by both beam and otter trawls, but rough weather caused the cancellation of beam trawis at three stations in April. Samples were collected near Port Angeles from four stations (1-4) within the ZSF boundaries and from two stations (5 and 6) east of the ZSF (Figure 9). All six stations were sampled with both beam and otter trawls. The exact locations and depths for all sampling stations in each of the six regions are recorded in Appendix Tables 1-6.
5
Quality Assurance/Quality Control (QA/QCI The location of each trawl station was found using a combination of radar ranges to permanent features and fathometer readings. When available, stations were located with LORAN C coordinates. Once the stations were located, the beam trawl was deployed at a target boat speed (relative to the bottom) of about 1.5 knots. Winch “wire out” at each station was set by precalculated ratios (ranging from 3:1 to 10:1, wire out:depth) that were dependent on depth and gear type. Each beam trawl was towed at a target ground speed of 1.4 knots for 1/8 NM (232 m) following pre-specified depth contours (for slopes) or compass headings (for flat bottoms). Elapsed time for each tow was monitored and the tow discarded if the elapsed time was 25% more or less than expected (i.e., 1.75 knots). Tows were also discarded and repeated if any other significant discrepancies were noted (e.g., gear hang-ups, tangled, torn or unexpectantly empty net, etc.).
Data Analyses All beam trawl catches of demersal invertebrates were converted to estimated densities based on calculations of the area swept by the beam trawl. Area swept was estimated from previous underwater measurements of net opening (2.3 m), observations of net behavior, and measurements of actual “net on bottom” times using ultrasonic transmitters on the net (Gunderson, unpublished data). In this report, the term “density” or “estimated density” (e.g., crab/ha) has been used without any corrections for net capture efficiency. Therefore, “densities” reported herein specifically refer to an index of estimated densities that should provide the best relative measures of demersal resources present as well as trends in abundances between areas, between seasons and between years.
6
RESULTS
Nisgually The Nisqually region of Puget Sound is extremely rich and diverse in inverte brate fauna. The habitat types are also diverse and include rocky areas around Ketron Island, current-swept sand bottoms off the Nisqually Delta, low current areas near several coves on Anderson Island and silty bottoms in and around the two ZSFs (Figure 4). Resources of potential fisheries importance included Dungeness (Cancer magister) and rock (C. productus and C. gracilis) crabs, pandalid shrimp and sea cucumbers. The area was also very rich in other invertebrate fauna, including starfish (a wide variety of species), sessil tunicates, anemones, brachio pods and gastropods. An occasional pink scallop was also caught along the west side of Ketrön Island. Dungeness craL2, Dungeness crab were caught in small numbers in front of and on either side of the Nisqually Delta (Figure 10). The average estimated density of crab for all seasons and stations combined (n
=
214 beam trawl tows) was 3
crab/ha, decreasing from 5 crab/ha in February to 1 crab/ha in October (Figure 11). Analyses of the basic biological data for this species (Figure 12) shows that all crab caught were large, mature individuals over 120 mm carapace width (CW). Females slightly outnumbered males in the catches except in October, when only several males were caught. Possibly, females were not caught in October because they had extruded new egg masses and were buried in the substrate (thus, un available to the trawl gear; Dinnel et al. 1988). A few gravid females were found in February with eggs ranging in age from medium to spent. The shell conditions of all Dungeness crab were hard to very hard
(=
old to very old) except in May, when
about one-third of females had recently molted (and probably mated during molt ing). The depth distribution of Dungeness crab varied by sex and season. Males
7
were usually caught in shallow water (≤20 m) except for October. Females were caught at all depths in February, in shallow water during molting and mating in May and to intermediate depths in July. The location of the females in October is un known, but information from other areas (Armstrong et at. 1987, Dinnef et al. 1988) suggests that females (probably gravid) move to relatively shallow areas during the fall/early winter. Rock crabs. Rock crabs (Cancer productus and C. gracilis) were much more plentiful (average for all beam trawis were Dungeness crab (average
=
=
156 crab/ha) in the Nisqually region than
3 crab/ha). In general, C. gracills outnumbered
C. productus by roughly 10-fold in the catches. The basic biological information for C. productus caught in the Nisqually area is summarized in Figure 13. Generally, females were more abundant in the catches than males except for October. Gravid females were most prevalent in the Febru ary samples, and the age of the egg masses varied from new to spent. Recruitment of juveniles started in about July. The young-of-the-year (YOY) dominated the catches in October and had grown to a size ranging from 10 to 30 mm. Both male and female C. productus occurred to depths >100 m, with little clear indication that a specific depth interval was favored. Similar biological data are summarized for C. gracilis in Figure 14. Males and females were caught in essentially equal numbers in February and May, while the catches were dominated by males in July and October. Gravid females and juve nile crab were caught during each season. The age of the egg masses also varied during each season. Hence, the spawning and settlement times for this species are distinctly less seasonal than for C. magister or C. productus. Cancer gracilis was found to depths of 100 m but generally favored depths 60 mm were found in Bellingham Bay in contrast to a relatively healthy population >60 mm in the Nisqually area (Figure 14). The reason(s) for the different age structure between the two areas is presently unknown. The distribution of C. gracilis was limited primarily to shallow areas in February and May, but covered all depths in July and October, in large part due to the wide distribution of the newly settled YQY (Figure 32). Tanner crab. Tanner crab (Chionoecetes bairdi—also commercially known as snow crab) were found in small numbers in the Beltingham Bay samples but would
12
have to be considered more of an “incidental observation” since this species does not support any fishery in the inland waters. The individuals caught in Bellingham Bay were mostly juveniles that probably settled from November-January and grew to an average size of ~-50 mm CW by October (Figure 33). Males slightly outnum bered the females (except in February) and their overall distribution was deep (2530 m) and restricted to the mid-bay area. Pandalid shrimp. Bellingham Bay proved to be relatively rich in commercial shrimp resources compared to many other areas of Puget Sound. All seven species of pandalid shrimp recorded in this study occurred in Bellingham Bay, although the spot prawn, P. platyceros, and the pink shrimp, P. jordani, were scarce (Figure 16). Bellingham Bay was especially rich in P. hypsinotus, P. danae, and P. borealis. The overall average (all seasons, stations and species combined; n
=
155 beam trawl tows) estimated density was 600 shrimp/ha with a seasonal range of 413 shrimp/ha (May) to 942 shrimp/ha (February). Shrimp were caught at most stations in Bellingham Bay, with the highest densi ties generally being caught in the deeper (25-30 m) mid-portions of the bay (Figure 34). The one exception to this was substantial catches of juvenile P. danae in July and October at some of the shallow areas (10-20 m), especially in the Post Point area. Relatively few P. platyceros and P. jordani were caught; hence, little information is available regarding timing of egg extrusion and juvenile recruitment. For the other shrimp species, egg-bearing females were only caught in the February trawls excepting a few gravid P. danae also found in the May trawls (Figure 24). No gravid P. dispar were caught. Recruitment of juvenile YOY shrimp was first noted for most species in the July trawls, except P. hypsinotus, which were not caught as YOY until October (Figures 1 7-23).
13
Besides providing estimates of shrimp densities, the trawl sampling also produced information on the age structure of shrimp populations in Bellingham Bay. For some species (P. platyceros, P. dispar and P. jordan,), only one yearclass of shrimp was evident in the trawls at any one time. For several other species (P. borealls, P. goniurus and P. hypsinotus), two year-classes were generally present while three year-classes were evident for P. danae (Figures 17-23). From these size-frequency plots, growth and relative abundances of each of the yearclasses can be traced. Other invertebrates, The large pink nudibranch, Tritonia diomedea, is considered a valuable neurophysiological research tool because of its large nerve fibers. Consequently, this species has been “harvested” in Bellingham Bay by researchers.from Friday Harbor Laboratory and elsewhere. Bellingham Bay is a favored collection site because this somewhat ephemeral animal can usually be obtained there. Our trawl sampling showed that the average estimated density of Tritonia in Bellingham Bay in 1987 was 13 animals/ha with a seasonal range from 21/ha (February) to 6/ha (October). The distribution patterns for Tritonia catches (Figure 35) showed that it was not abundant anywhere in Bellingham Bay, but that the bulk of the animals caught were found at the deeper (20-30 m) stations in the mid-portions of the bay. Compared to the Nisqually area, Bellingham Bay was relatively poor in starfish diversity. However, there was a high biomass of the fragile starfish, Luidia foliolata. This species is singled out for two reasons: (1) It occurred in large numbers and biomass in some of the trawls and (2) this species has been reported to be a nuisance by-catch in the bottomfish trawl fishery in this area, so much so that some areas of the bay are avoided by the fishermen (Gary Davis, pers. comm.). The’seasonal distribution patterns of the Luidia catches (Figure 36) show that this species was caught at most stations in the bay, but that the highest catches
14
were generally from the southern, mid-portion of the bay. The average overall estimated density of starfish for all trawls (n
=
155 beam trawl tows) in Bellingham
Bay in 1987 was 256 starfish/ha, of which 242/ha was Luidia. The Luidia popula tion was relatively stable between seasons, ranging from a low of 198 individuals! ha (October) to a high of 319/ha (July). By-station and by-season densities of Luidia in Bellingham Bay are summarized in Appendix Table 7. Other than Tritonia and Luidia, few other invertebrate “resources” were noted from Bellingham Bay (Figure 26). Bellinçiham Bay disposal areas. Five stations were sampled each season by beam trawl in or close to each of the two proposed ZSFs in Bellingham Bay. The average annual estimated densities (all seasons and stations combined, n
=
20
beam trawl tows for each ZSF) for each of the invertebrate “resources” listed in Table 2 show that Dungeness crab were least plentiful in the south ZSF, rock crabs and Tritonia roughly the same in each ZSF, and shrimp and starfish (essentially all Luidia) in greater abundance in the south ZSF. Only in the case of shrimp (south ZSF) and Tritonia (south ZSF) did “resource” densities in the ZSFs exceed the baywide averages (Table 2) and, in the case of Tritonia, the relatively high average was caused by a one-time peak density of about 55 Tritonia/ha in February. Table 2. Summary of the average density (#/ha, all stations and seasons combined) of major biological resources caught within the Bellingham Bay zones of siting feasibility (ZSF) and at all stations combined. Resource Dungeness crab Rock crab Pandalid shrimp Sea cucumbers Starfish Tritonia
North ZSF
South ZSF
46 9 488 0 99 18
23 8 764 0 212 26
All stations 83 40 600 few 256 13
15
Figures 37 and 38 graphically illustrate the average densities of invertebrate resources caught by beam and otter trawls in each ZSF for each season. Com parison of these two figures shows the greater efficiency of the beam trawl for sampling invertebrate resources with the exception that estimates of shrimp densities were generally higher for the otter trawl.
Strait of Georgia The preliminary ZSF sited in the southern Strait of Georgia south of Point Roberts is located in deep water (200-210 m depth) close to the U.S.-Canada boundary and in an area of high currents, turbulence and mixing. The northern portion of the ZSF is located over a sand bottom where large catches of brittle stars were common; the southern portions of the ZSF bordered on a rocky bottom (characteristic of Alden Bank and the Patos, Sucia, and Matia islands) where catches of mussels (Modiolus) and sea urchins were possible (as well as rock damage to the trawls). In general, invertebrate resources were sparse in and around the proposed ZSF. The distributions of Dungeness crab, shrimp, scallops and sea urchins are
graphically presented for the April and October cruises in Figures 39 and 40. Dungeness crab. No Dungeness crab were caught within the boundaries of the ZSF during either cruise. This species was limited to depths ≤100 m and were especially abundant at the 50-rn station (Station 10) as has also been shown during previous sampling at this location (Dinnel, unpublished data). The average densities of Dungeness crab for each cruise (excluding Stations 5 and 7, n
=
9
beam trawl tows each season) were 46 crab/ha in April and 17/ha in October (Figure 11). Note, however, that these averages are based on catches of crab at only 3 of 11 stations (Stations 9, 10, 11), and that the average densities for only
16 these 3 stations would be 138 and 50 crab/ha for April and October, respectively. Hence, the preferred areas for Dungeness crab appear to be outside the ZSF. Figure 41 details some of the basic biological data for Dungeness crab in the Strait of Georgia. Males dominated the catch by about 2:1 over the females, and juveniles were rare. The majority of the females caught in October were gravid with new egg clutches, while one female caught in April had a spent egg clutch. Shells were hard for all crabs caught in both April and October. The size-frequency plots in Figure 41 show that most crabs in the catches were mature adults over 100 mm CW with the very notable exception of a group of subadult males between 80-100 mm CW caught in April. This observation is significant because our sampling has rarely identified habitats utilized by 1- to 2-year-old crabs (i.e., 30-1 00 mm ani mals). This.information—and the depth-distribution graphs of Figure 41—suggest that subadult males distinctly prefer the 50-rn contour off Birch Bay. Rock and tanner crabs. Rock and tanner crabs were relatively scarce in the Strait of Georgia samples (Figure 11). Pandalid shrimp. Pandalid shrimp catches were spotty and relatively small. The average estimated densities for each season (excluding Stations 5 and 7; n
=
9 beam trawl tows) were 44 and 71 shrimp/ha for April and October, respectively. The catches primarily contained P. danae at the shallower stations and P. borealis at the deeper stations, with an occasional P. dispar in the catches (Figure 16). Size-frequency distributions for each shrimp species caught in the Strait of Georgia (graphed in Figures 17-23) show that several year classes of P. d!spar P. danae and P. borealis were present. Other invertebrate resources. Both pink scallops, Pecten rubida, and weathervane scallops, P. caurinus, were caught in very small numbers at a few stations (average of 6 and 19 scallops/ha for April and October, respectively; n
=
9
17
beam trawl tows) each season (Figure 40). Weathervane scallops were rare compared to pink scallops. A few sea urchins (Strongylocentrotus pallidus) were caught within the ZSF, indicating a hard bottom in the southern portion of the ZSF (Figure 40).
Rosario Strait Rosarlo Strait is a current-swept passage lying between Decatur and Lopez Islands on the west, Fidalgo Island to the east and Cypress Island to the north. The bottom type ranges from gravel in the northern portion to cobble and rock outcrop pings in the southern portion. Eleven stations in Rosario Strait were sampled by rock dredge during April and October. Each tow with the rock dredge was roughly 0.1 NM. Since the sampling efficiency of a rock dredge bouncing on a rocky bottom must be very poor, no attempts were made to estimate resource densities from the these tows. Crabs. Dungeness and rock crabs (except for small and plentiful Cancer oregonensis) were completely absent from the rock dredge samples during both seasons. Shrimp. A relatively large number of small, non-pandalid shrimp were caught in the rock dredge, but only a few pandalid shrimp (mostly small P. danae; Figure 19) were caught at each station (Figures 16, 42 and 43). Other invertebrate resource& Pink scallops were fairly common in the rock dredge samples from the southern half of Rosario Strait and absent from the four northernmost stations, which typically had sand and gravel bottoms (Figures 42 and 43). Sea urchins (S. pallidus) and mussels (Modiolus) were also caught in fairly large numbers at the southern stations (Figures 42 and 43). Catches of these species at the southern stations indicates a very rocky bottom.
18
Port Townsend The Port Townsend ZSF was located northeast of Port Townsend at the head of Admiralty Inlet. Six stations were sampled in and around the ZSF with both beam and otter trawls (except that three stations were not sampled by beam trawl in April because of high winds and rough seas). The station depths ranged from 70 to 150 m. The bottom was probably a mixture of sand, small gravel and shell. Crabs. No Dungeness, rock or tanner crabs were caught in this area during either sample season. Pandalid shrimp. A modest average donsity of 236 shrimp/ha (all stations combined; n
=
6 otter trawl tows) was estimated for this area in April. The average
density of shrimp estimated in October otter trawl catches increased dramatically to 6,802 shrimp/ha, primarily due to an influx of young P. danae and P. borealis (Figure 16). The distributions of shrimp in the Port Townsend area were similar during the two seasons sampled (Figures 44 and 45) and the highest catches were made at Stations 4 and 6 (stations closest to Port Townsend). In each case, the catches were dominated by P. danae. Few shrimp were caught at Stations 1 and 5. Pandalus platyceros, P. jordani and P. hypsinotus were not caught in this area, and relatively few P. dispar and P. goniurus were in the catches. The few P. dispar that were caught were mature shrimp averaging about 25-30 mm CL except for a few juveniles caught in October (Figure 18). The few P. goniurus, caught only in October, were all juveniles averaging 10 mm CL (Figure 22). P. borealis caught in the April sampling were of two size groups, averaging about 10-12 mm and 16-17 mm CL, while the October samples were dominated by YOYs averaging 9-10 mm (Figure 21). The size-frequency plot for P. danae (Figure 19) caught in April also suggests there were two size groups for this species, averaging 10-12 mm and 1720 mm CL. The number of P. danae caught in October also increased roughly two
19 orders of magnitude but, unlike P. borealls, the increase in numbers appeared to be due to an influx of 1- to 2-year-old animals rather than due to settlement of YOY (Figure 19). Other invertebrates. Pink scallops were abundant at some of the Port Townsend stations, although the catches were spotty. The scallop catches (based on the October beam trawl samples—sampling with this gear was incomplete in April and the otter trawl is a poor sampling gear for scallops) were highest at Stations 1 and 4, with estimated densities of 2,172 and 8558 scallops/ha, respect ively; and lowest at Stations 2, 3 and 5, where no scallops were caught in October (Figure 44 and 45). At present, it is unknown how consistent these apparent aggregations of scallops will be in future years. Large numbers of sea urchins (S. palildus, possibly S. droebachiensis, and a few rare Allocentrotus) were caught at three of the Port Townsend stations (Stations 1, 4 and 6), which were the same stations where the highest scallop catches were made (Figures 44 and 45). The estimated urchin densities at these three stations (based on October beam trawls) ranged from 2,079 to 8,521 urchins/ha. Very few urchins were caught at the other three stations (Stations 2, 3 and 5). Other invertebrate “resources” were limited primarily to modest numbers of a variety of starfish species (Figure 26). Port Angeles The Port Angeles ZSF is located north of Port Angeles and Ediz Hook in the middle of the Strait of Juan do Fuca and adjacent to the international boundary. The eastern portion of the ZSF is also adjacent to a rocky reef area locally known as the “rock pile” (a popular fishing spot). The station depths ranged from 110 to 136 m and the bottom type was apparently a sand/gravel mix with some shell.
20
Crabs. As was true for the Port Townsend site, no crabs were caught in the Port Angeles ZSF. Pandalid shrimp. Few shrimp (average density
=
53 shrimp/ha; n
=
6 beam
trawis) were caught in the trawls in April, and the majority (—90%) of those caught were P. borealls (Figure 16). However, catches of shrimp in October jumped more than two orders of magnitude (average estimated density
=
6,775 shrimp/ha) owing
entirely to settlement of YOY P. borealis averaging about 8-9 mm CL (Figure 21). Unlike Port Townsend, no P. danae were caught in the Port Angeles area. The balance of the shrimp catch at Port Angeles consisted of a few P. dispar and P. goniurus. The distribution of the April shrimp catches was uniformly low at all stations and the largest catch (206 shrimp/ha) was at Station 5 (Figure 46). However, the very high catches in October were not evenly distributed; about 94% of the shrimp were caught at only 3 stations (Stations 1, 2, 3) with catches of 26,462 to 68,927 shrimp/ha (Figure 47). Other invertebrates. Pink scallops were caught in large numbers in April (average beam trawl density = 2,781/ha) and October (average
=
1,323 scallops!
ha). The highest densities (up to 4,551 scallops/ha) were caught at Stations 2, 3, 4 and 5 during each season. Scallops were essentially absent from Station 6 (Figures 46 and 47). Sea urchins (S. pallidus) were also plentiful in most of the trawl samples from Port Angeles during both seasons (average densities
=
1,486 and 2,260/ha for
April and October, respectively). However, unlike Port Townsend, the highest sea urchin densities did not correspond to high scallop densities. The highest sea urchin catches were at Station 6, which was almost devoid of scallops. The distri bution of sea urchins was fairly uniform between stations, with Stations 5 and 6 producing the largest catches during both seasons (Figure 46 and 47).
21
Other invertebrate “resources” caught in the Port Angeles area were limited to moderate numbers of a variety of starfish species and a few sea cucumbers (Figure 26).
DISCUSSION AND CONCLUSIONS
Nisgually Region In 1987, the primary invertebrate species of actual or potential commercial and sport fishery concern caught in The Nisqually region were Dungeness and rock crabs, pandalid shrimp and sea cucumbers. Dungeness crab were sparse yet of concern for two reasons: (1) crab were caught near the south boundaries of both ZSFs, and (2) this population of crab supports a small sport fishery in the Nisqually Delta region~(Ron Westley, per. comm.). The recruitment dynamics of Dungeness crab in this area are unknown, but larvae may come from the few local resident females or recruitment might be dependent on larvae transported southward through the Tacoma Narrows from the main basin of Puget Sound. The generally shallow distribution observed in May might be a reflection of mating and molting activities. All Dungeness crab caught in the Nisqually region were mature indi viduals over 120 mm CW. This size distribution suggests that these animals all came from one or two successful periods of juvenile recruitment about 3-5 years ago and that settlement has not been successful in recent years. The larger sizes of Dungeness crab from the Nisqually (especially the females), together with a general appearance of good health, suggests that the Nisqually area could support more Dungeness crab if settlement (and/or juvenile survival?) were more successful.
Other Cancer crabs present in the Nisqually region were the rock crabs C. productus and C. gracills. Cancer productus is utilized for food by some sport
22 crabbers and divers, while the more plentiful C. grad/is is less extensively fished because of its smaller size. Rock crabs tend to be more important in sport catches when Dungeness crab are unavailable. Cancer productus is also a potential commercial species, since the large claws of this species now appear in California fish markets. Pandalid shrimp were generally sparse in the Nisqually region with the possible exception of P. danae. However, most of the P. danae were young individuals (CL 100
OCTOBER
20 ID U
—~
ID
20
40 60 DEPTH (m)
80
‘100
Figure 12. Summary of Dungeness crab depth distribution, size frequency, shell condition, sex composition, female reproductive condition and egg age in the Nisqually region during four seasons of 1987.
41 CANCER PRODUCTUS
-—
NISQUALLY
SEX
I
• JUVENILE QMM~E I FEMA~
~
I~1
U
‘a’
AGE OF EGGS
FEMALES 120 100 80 ~6O ~ 40 20
0~fL1i FE~
MAY
.Hhl~Y
60 50 40 30 20 10
D NOTGRAVIOI •GRAVlD~
• ~ cEo ~ HATcHiNG
t~
FEZ
OCT
JULY
MAY
DEPTH DISTRIBUTION
SIZE FREQUENCY
MALE 10
40 20
2 4_,._..1nrrr.ntrI..4pI.I.II..L.~glrIpr
0
20
40
60
80
100
120
140
IFri 10
160
MAY
0
20
40
-~ 60
100
8
80
6
60
80
>100
MAY
40
P
20
E R C E N T
FEBRUARY
60
4
U
FEMALEI
80
J U V
6
C
100
FEBRUARY
8
OCT
A60 .JULY
~0 ‘°
40
100
F~T1 10
120
20
40
60
100
80
>100
JULY
80 60 40 20
~
J
40
OCTOBER
1ii~fl 10
~~1401~0
20
a
60
100
80
>100
OCTOBER
80 60
~ 11 0
20
40
40
A
20
AAAiIII
80 100 60 CARAPACE WIDTH
120
(mm)
140
160
I
I0~
20
40 60 DEPTH Cm)
80
>100
Figure 13. Summary of Cancer productus depth distribution, size frequency, sex composition, female reproductive condition and egg age in the Nisqually region during four seasons of 1987.
42 CANCER GRACILIS
---
NISQUALLY
SEX 6O~
r.
SO
JUVENILEl DMALE I ~ FEM~J
40302010-
~ ~
AGE OF EGGS
FEMALES
i1I~i
[i~r0.~b0I
us
‘5
us
a.
FE~
HAT
FE~
ocr
.~LT
HAY
-
juLy
rw~ c FEBRUARY
~
8
lu
6
—
4
R IEW
ocT
DEPTh DISTRIBUTION
SiZE FREQUENCY
10
~ MEDIUM ~] OLD ~ HATCHING Q SPENT
FErIALEj
100
FEBRUARY
80 FEMALE
60 MAIl
80
~t
20
MAY
10 8)1
40
20 100
-i 10
20
40
80
80
100
MAY
80
6u
V 4
P E R C E N T
40
~ 20
AAA1~ 40
A 60
1I:nI~i
..
60
100
I0
120
JULY
100
8
80
6
60
4
40
2
20
40
60
60
100
10
120
OCTOBER
8
JULY
20
L~kAAJAj’2~
10
80>100
20
40
60
100
60
>100
OCTOBER
80
6 4
\
2 0 0
~II-1J-1w.-,I1 40 60 60 100 CARAPACE WIDTh (mm)
120
10
20
40 60 DEPTH Cm)
—
80
---
>100
Figure 14. Summary of Cancer gracilis depth distribution, size frequency, sex composition, female reproductive condition and egg age in the Nisqually region during four seasons of 1987.
Figure
15.
Maps of the Nisqually region showing the densities of commercial pandalid shrimp as estimated from beam trawl catches in February, May, July and October 1987.
SHRIMP MAY
c~)
44 r~~lMATED DENSITIES OF PANDALID SHRIMP
I
BELLINGKAM BAY
NISQUALLY 300 250 200 ISO I00 50 C
P1.AW N U
300 250
OISP
DANAE
J~D
Bc~E
HYPS
PLATY N U PA B
300 250 200 150 100 50
E R P E R
300 250 200 ISO 100
H A
I
DANAE
JQ~0
BC~E
HYPS
-I-Il 0ISP
DANAE
JcH~D
S~S
HYPS
OISP
OANAE
J~D
BORE
PIATY
1
P E R
300 250 2001 1501
OISP
OANAE .JC~D
PL~TY
OCt41
OISP
DANAE
E
R H A
u B
DANAE
J(*D
BORE
HYPS
R T o OANAE JORD
BORE
OISP
u PA E R
300 250 200 150
HYPE
0041
APRIL
W
300 250 200 150 100 50 C
N
300
u
250
u _________________
PtATY
01W
DANAE
.JORD
BORE
HYPE
B E R
DANAE
.IORD
BORE
HYPS
OCt41
I
OANAE JORO
BORE
HYPS
OCt41
01W
OAP4AE .JORD
BORE
HYPE
6041
0ANAE JORO
BORE
HYPE
0011
HYPE
OCt41
HYPE
OCt41
OCTOBER
PtATY
01W
HYPE
0041
APRIL.
~o 0 PUJY
H A 01W
S~E
200 150 100
0011
E R
Pt.ATY
JC4W
PORT ANGELES
~
a
GONI
APRIL.
PORT TOWNSEND N
HYPS
_
Pi.ATY
E
100 0l5P
300 250 200 ISO 100
0041
OCTOBER
PtATY
B~E
ROSARIO STRAIT (ROCK DREDGE)
APRIL
01W
OONI
OCTOBER
Pt.ATY
N
PtATY 300 250 200 150
HYPS
_
OCt41
~oo 250 200 ISO 100
e~
.iut.v
STRAIT OF GEORGIA N U M B
J~D
loot
H
300 250 200 150 00 50 CHYPS
DA14A~
______________
ZERJ3 Pt.ATY
DISP
MAY
oce~i
JULY
Pi.ATY
300 250 200 ISO 100 50 0
OISP
—~
GONI
MAY
PtATY
FEBRUARY
300 250 200 150 100
01W
OANAE ~JORD
OCTOBER
BORE 21.fl~
~ PtATY
01W
0ANAE JORD
BORE
Figure 16. Summary of estimated average densities (#/ha) of pandalid shrimp by area, by season and by species based on the beam trawl catches (except #Itow for the rock dredge used in Rosario Strait).
45
I Pano’a/usplatyceros NISQIJALLY
BELLINGI-tAfi BAY 30
30
20
10
IS
: ~ : : i: : : : :i:i:301~1 : 0
S
10
R C E
15
20
30
30
35
30
MAY
30
p E
FEBRUARY
FEBRUARY
20
20
p
20
I0
E
0
R
C
30
E
30
N
20
N
20
T
0
T
JULY
10
S
l~
10
30
30 20
20
IS
IS
0j0
OCTOBER
30
~A1AFA~ L0~T~
0
5
30
p
10 5
10
5
20
33
30
30
E R C E N
OCTOBER
T
20
33
23
30
33
35
30
-
APRIL
20 IC 0
0
IS
20
OCTOBER
30 20
IS IS 20 25 CAIAP&U Lmrw ()
30
iS~~
30 CAIA#AU L~ITW ()
PORT ANGELES
PORT TOWNSEND APRIL
30
APRIL
30 20
20
P
IC 0
5
10
IS
20
25
30
33
OCTOBER
30
E R C E
N T
20
IS 0
S
30
25
30
35
10 IS 20 23 CAIAPA~ LtS~TS (~)
30
35
10
IS
20
OCTOBER
20 IS
10 05
Figure 17.
30
0 15 20 23 CAW~ L01Th (~)
Co S
T
35
IC
l0
P E H C E N
30
ROSARIO STRAIT
APRIL
30
23
0
30
(a•)
20
p E R C E N T
20
OCTOBER
STRAIT OF GEORGIA 30
IS
10 IS 20 25 0AlAPA~ LIOST1I ()
30
35
0
5
Size frequency distributions for spot prawn, Pandalus platyceros, caught by both beam and otter trawis combined (except rock dredge in Rosarlo Strait) by area and by season for 1987.
46 Pandalopsis a,cpar
~ N SQUALLY
BELLINGRAM BAY 30
30
20
10
0 0
5
30
c E N T
FEBRUARY
FEBRUARY
20
0
15
20
25
30
0
35
30
MAY
0
5
0
1..iI. . . .i
15
20
25
30
35
JuLY
~° 20
i 0
5
.11.
~
p E R C E N T
•1 0
IS
20
25
30
30
MAY
l0 0..
5
0
15
20
25
JULY
10 0
5
10
5
20
25
APRIL
P
10
c 0
.
5
Ia
-
j5
CARAPACE L.E~TN
ROSARIO
N T
APRIL
P
E Fl •30
3
~
30
STRAIT
20
-
2S~
(mm)
30
III iii ~ 20
35
JJL.1 .
(mm)
STRAIT OF OEORGIA 20
30
OCTO8ER
C
30
35
20
OCTO8ER
CARAPACE L~RSTH
30
30
20
E R c E
2530
20
C
35
015
OCTO6ER
C E N T
10
e 051015
2025
35
30
OCTOBER 20 10 1’
0
5
10
15
20
CARAPACE LERRTH
25 (mm)
30
5
35
10
30
~_ ~
T N
5
10
15
20
35
31)
35
~0CT00~Ii
‘°
c 20 30 10 U
0
5
10
75
20
CAAAPAcE LERRTh
Figure 18.
25 (mm)
30
35
25 (mm)
30
35
APRIL
20
P E B C
0
20
PORT ANGELES
PORT TOWNSEND
C
15
CARAPACE LE~TN
II
:-ttL’520j1Jz CARAPACE LEH8TN
Cm.)
Size frequency distributions for sidestripe shrimp, Pandalopsis dispar, caught by both beam and otter trawis combined (except rock dredge in Rosarlo Strait) by area and by season for 1987.
47 Panda/us danae NISQUALLY
BELLENGHAM BAY 30
30
FEBRUARY
r
C’
............_
I
5
10
IS
20
25
30
0
35
5
0
Lii
MAY
20 Ia • :5:
3
35
30
I 20
25
30
p E R C
20 0
~1
510
JULY
T
un.
30
20
25
30
_II1IIIpII
2
-
5
10
15
20
25
30
OCTOBER
35
JULY
I’
~
15
20 I0
o.
35
MAY
~30
20 10
30
35
OCTOBER
20
20 10 0
5
lIiIIiIh_
IC
_..i,IIIIh..~..i
10 15 20 25 CA~APAU UNGTN (m)
30
0
35
5
0 15 20 25 CARAPA~LENBTh (~~>
30
35
ROSARIO
STRAIT OF GEORGIA 30
30
APRIL
APRIL 20
20
p E R C E N T
15
30
30
r
11111111
l0
I Ili.ii_.~ _iIii_~
0
p E R C E N
FEBRUARY
20
20
10
~
OCTOBER
N 7
20 10
i~ 1.1111 I
110 15 20 CARAPAcE LENGTh
OCTOBER 20
10 o~• 25
30
35
..iiIL11iii
20
CARAPAcE IINST14
(tm)
25
30
35
(m)
PORT ANGELES
PORT TOWNSEND 30
30
APRIL
APRIL
20
p E R C E N T
_ililii_ii_IIi_
10
~ 0
5
~
0
15
20
25
30
OCTOBER
N 7
20
15
20
OCTOBER 20 10
IC 0
Figure 19.
~s
35
5
10 15 20 25 CARAPAcE I1NGT)4 ()
•
35
0
5
10 IS 20 25 CARAPACE LENGTH (~)
-
Size frequency distributions for coonstripe shrimp, Panda!us danae, caught by both beam and otter trawis combined (except rock dredge in Rosarlo Strait) by area and by season for 1987.
48 Panda/us Jordan! N SQUALLY
BELLINGIIAM BAY 30 20 10 05 30
I 0
30
FEBRUARY
FEBRUARY
20
I 15
20
25
30
35
)
MAY
p E
10
10
R
r
E N T
....
5
10
15
20
25
30
~1]
35
R
c
c
115
.~
.
20
25
0
5
III.. 20
10
15
30
25
~ ~ iL
35
~
OCTO8ER
005
IS
..~..
CAaAPACE LE~ST14 (..)
35
MAY
20
0
10
30
20
C
I I
S
30
35
~.
OCTOBER
•.
~.
CARAPACE LENGTH (m.)
STRAIT OF GEORGIA 30
ROSARIO STRAIT 30
APRIL
APRIL
p
E R C
B N T
~
0
~•‘25
~ OCTOBER
20
C N T
.
10
~0
0
~
25
3ó~5
OCTOBER
20 10
C 0
5
10
15
20
cAaApAC~ L1~fl4
25
30
C
35
0
5
(m.)
10
15
20
CARAPACE LENGTH
PORT TOWNSEND
25 (me)
30
35
PORT ANGELES 30 20
p
p
B R
B
C
~
B N T
30
~0•~
~
OCTOBER
20
10
R C
0
B
30
N T
20
~PRIL OCTOBER
10
10
C 0
5
10 15 20 25 CAGAPAU LENGTH (m)
30
35
0
S
10 15 20 25 CARAPACE LENGTH (mm)
30
35
Figure 20. Size frequency distributions for the pink shrimp, Pandalus Jordan!, caught by both beam and otter trawis combined (except rock dredge in Rosario Strait) by area and by season in 1987.
49 Panda/us borealis NISQUALLY
BELLINGKAM BAY 30
30
FEBRUARY
_1i!0Ii .~.1.~~
20
to
30
25
30
-
FEBRUARY
35
~.
MAY
MAY 20
20 10
P E R C E N T
i~I.II. ~II1.i;
.5
30
-
0
5
__IIIII__I 0
5
1.IUL.i1i~
10
p 20
25
30
30
35
Jul-v
20
N
e 30
OCTOBER
20 Ill
I•frr.-rrv, ..ii_.
I
-.,--
1
5
10
IS
20
CARAPACE LERTI4
25 (.)
30
CO
35
1520 CARAPACE LE~SflI
ROSARIO STRAIT
STRAIT OF GEORGIA 30
30
APRIL P B R
10 0
01520
25
30
30
35
OCTOBER
10
r
C
B N T
20
0
5
10
15
0
20
30
35
OCTOBER 20 15
~
5~ CARAPACE LRAGTU
25
30
10
I0
“
APRIL
20
20
R C B N T
253035 (ma.)
CARAPACE LRNRTH
(mm>
(mm)
PORT ANGELES
PORT TOWNSEND 30
APRIL
20
P B R C B N T
2
10
15
20
~ 20 ‘U 0
2
5
iii’ 10
25
30
35
OCTOBER
N T
OCTOBER ~ 10
~ 15
20
25 CARAPACE LINGIH (mm)
30
35
0
5
•_..a_II___ 10
15
20
CARAPACE LEmRTH
-
25 (mm)
30
35
Figure 21. Size frequency distributions for the pink shrimp, Pandalus borealis, caught by both beam and otter trawis combined (except rock dredge in Rosario Strait) by area and by season in 1987.
50 Panda/us gon/urus NISQUALLY
BELLINGKAM BAY 30 20 10 —
0
5
11I1L 0
30
FEBRUARY
10
15
20
25
30
30
~
0
35
S
0
IS
20
25
30
30
MAY
35
MAY
20
20
P E R C E N T
FEBRUARY
20
P E
10
10
R 0
i0~’~~20
25
30
30
JULY
20
C E
~o
N T
20
0
iaiS
5
2025
3035
JULY 10
10
I. 0
~
0
5
10
30
OCTOBER
20
IC
10
0
.: :~:
•
I~~IIiI~~ ~ CARAPACE LRI~TI4 I,.-)
0
APRIL p E 0
5
20 10 0
:
10
15
5.i[.:~5
20
25
30
35
OCTOBER
~
E N
T
~
CARAPACE IFW~fll (‘—0
APRIL
10
-
0
0
5
0
APRIL p E
~a :::.:.::::.:....:.:::::.
‘0
15
20
25
30
35
OCTOBER 20
35
C0::.::5ii~óh1.::~ó:25:.3O ~ APRIL
El C E N T
~ __________________
o 30
5
10
15
20
25
30
35
OCTOBER
20 I0
10 0
Figure 22.
30
30 20
p
5
25
PORT ANGELES
20
o
20
OCTOBER
PORT TOWNSEND
30
15
CARAPACE LINRTN (ri)
30
E N T
35
El
~
I
30
20
~
C
35
ROSARIO STRAIT
p
C
30
30
20
E R
25
15 20 25 CARAPACE L1~fl4 (~)
STRAIT OF GEORGiA 30
E N T
20
OCTOBER
20
E El
15
30
5
10 15 2 25 CARAPAcE LENGTh (ii.)
30
35
1 0
15 20 25 CARAPACE L!RRTH (~)
30
35
Size frequency distributions for Pandalus goniurus caught by both beam and otter trawis combined (except rock dredge in Rosario Strait) by area and by season in 1987.
51 Panda/us /Iyps/notuS BELLINGHAM BAY
NISQUALLY FEBRUARY
3°
FEBRUARY
~°
~0
-
~
~
MAY 20
II II
p
E R C E N T
MAY 20
10
p
,_._i.i. IL..,
~ 0
5
10
IS
20
E R C E N T
.
3°
30
JULY ii
20
10
~ ~
5
10
15
30
35
JULY 10
C
0
5
10
,__.I
IS
20
25
30
30
•_,_,_.
t
35
0
5
0
OCTOBER
APRIL
20
p ..
0
5
10
15
20
25
30
35
OCTOBER
E R
~
C
3o
E N T
20
10
C
APRIL
20
10
E N
35
ROSARIO STRAIT 30
20
30
30
c*~*cz U~TH (m)
STRAIT OF GEORGIA
C
25
20
30
~
20
OCTOBER
CAIAPA~ L~NSTh (ii.)
E R
15
30
20
0
5
10
15
20
25
30
35
OCTOBER 10
0
5
10 15 20 25 cAaAPAU LEGfl4 ()
30
CI..: 0
35
:.::
5
:::
-.
10 15 20 25 £A~APAtt LENGTH Cm.)
PORT TOWNSEND
30
35
PORT ANGELES APRIL
3°
APRIL
~°
20
T
25
20
10
p E R C E N
20
30
20
p
E
~o _________________
0
10
31)
~35
~
OCTOBER 20 10
~
N T
20
_________________
05~Ol5
20
2530
35
OCTOBER IC
c~.. 0
Figure 23.
~o
R C E
5
10 IS 20 25 EARAP*~ I ENGIII ()
30
35
0
0
5
10
15
20
CAEAP*~ I FNGflI
25 Cm.)
30
35
Size frequency distributions for humpback shrimp, Pandalus hypsinotus, caught by both beam and otter trawis combined (except rock dredge in Rosario Strait) by area and by season in 1987.
52 Sil1R~P REPRODUCT~VE CO~DllT~ON
r~ E R C E N T
NOT ORAVID
120
P~qndgIusdan,e --BELLINGHAM BAY
120
p
11
Z ORAVID
100
100
80
80
§0
60
40
40
20
20
Panda/us danae
FEB
Panda/us borealis
120
P E R C E N T
100
--
BELLINGHAM BAY
--
NI SQUALLY
JULY
MAY
P,nda~/us borealis
--
OCT
NISQUALLY
IllIllllflhIII
80 60 40 20 0
-
FEB
MAY
JULY
Panda/us hypsinotus
120
—
.4-
OCT
BELLINGI-IAM BAY
120
P
100
100
~
80
80
C
§0
60
~
40
40
T
20
20
C,
-
—
FEB
—4
—
MAY
JULY
SEASON
Figure 24.
Panda/usg’oniurus-- BELLINGHAM BAY
OCT
FEB
MAY
JULY
OCT
SEASON
Selected shrimp reproductive conditions by area, by season and by species.
Figure
25.
Maps of the Nisqually region showing sea cucumber densities as estimated from beam trawl catches in February, May, July and October 1987.
SEA CUCUMBER
CA)
54 r~3TIMATED DENSITIES OF I OTHER INVERTEBRATES j
I
NISQUALLY
BELLINGHAM BAY 300 2~0 200 150 l00 50
FEBRUARY
SCALLOP TRIT0NIA
N U M B E R
300 250 200 150 100 50 0
p E R
300 250 200 150 ISO 50 C
H A
300 250 200 ISO
L~OSN
1jIJSS~
MAY
CXIIII
SCALLOP TRITONIA
URDAN
IOJSSE.
Jul-v
CXIII
-
SCALLOP TRIrQNIA
1150AM
1111515.
I
I I STARFISH
300 250 200 150 100 50
c~IqJH
N U U B E R
50 CXIII
SCALLOP TRITONIA
1150AM
1111W..
CXIII
STAJflSH
p E R
100 50
P E R H A
300 250 200 ISO
1150AM
1115515.
a
100
I
11
~4
sr~wiSH
ic*u.y
miralSA
~aois
APRIL
rssssa
STARFISH
SCALLOP 1111051*
1150AM
1115W..
STARFISH
I
APRIL
200 150 100 5
I
—. CUCUM
SCALLOP TRIIONIA
1150AM
FIJSSEI.
CXIII
SCALLOP TRflORIA
115054
1115515.
STARFISH
OCTOBER
STARFiSH
PORT ANGELES N U U B E
a
cx~.
LIIaRN
~
PORT TOWNSEND N U U B E R
SCALLOP TRITORIA
300
STARFiSH
T 0 ~1W.
ISJSURL
I
tROcZ 01150615)
OCTOBER
t~cisis
STARFISH
ROSARIO STRAIT
P E
SCALLOP mflosIA
IIJSXI.
OCTOBER
CXIII
a
rRrroRIA
IIICI*N
JULY
CXIII
300 250 200 ISO
I
ISO SCALlOP
STARFISH
50
STARFISH
APRIL
CXIII
lSjSS~.
ISO
H A
N U U B E
a
SCALLOP TRITOI4IA
300 250 200 150
STARFISH
350
250 200
L*DIIN
MAY
STRAIT OF GEORGIA N U M B E
SCALLOP TRITSAIA
300 250 200 ISO ISO 50
OCTOBER
ISO
FEBRUARY
STARFiSH
tj[2[i COORS
p E
P E
a
a
H A
H A
SCALLOP TRITOISIA
UscisM
isssa
STARFISH
ii[J[IR COORS
XM~OP
1511051*
0112415
1115515.
STARFISH
Figure 26. Estimated average densities (#/ha) of various invertebrate species caught by beam trawl (except #/tow for rock dredge in Rosario Strait) in 1987 by area, by season arid by faunal group.
55 NISQUALLYDISPOSALS1T~ BEAM ¶fl~AWL SAMPLES
FEB
I
LMAY III JULY ~ OCT ZSF #3
ZSF # 2 N U U B B A
80
p
40
E
CRAB
60
A H A
20 ——
0 MA6ISTER
PRODUCTUS
J~ SRACILIS
N U hi a £ A
CRAB
p £ A H A MABIS1ER
TAIB~*
PRODUCTUS
N U U B I A p B I’ H A
50
SHRIMP
40 30 20 10 0 Pt.ATY DISPAR DAllAS
.3085
JL1 eONSAL
N U hi I I A
50
p I N
20
H A 8081
300
I N
200
a
SHRIMP
30
10 PLATV DISPAB DAllAS
N U U B I N
STARPTSH
250
N A
p I N
l00 50
H A
U
FEB
N U U B I B p I A H A
15
MAY
N U hi B I A
12 9
p I A
6 3
H A I
FEB
MAY
.3085
NYPSIN
300 250 200 ISO 100 50 0
15
SEA CUCUMBERS
12 9 5 3
NOT
‘I
JULY
BOWl
OCT
JULY
SPA CUCUMBERS
0
ii
BOREAL SIWMP SPKIES
IISPIIK
ISO p I B
TANNER
40
SHRWW SPECIES
N U II
BRACILIS
CRAB SPECIES
CRAB SPECIES
OCT
FEB
PlAY
JULY
OCT
Figure 27. Comparison of average beam trawl catches (estimated #/ha) by species and by season between Nisqually ZSF 2 and ZSF 3.
56
NISQUALLY DISPOSAL SITES O1TER TRAWL SAMPLES
I
• FEB D MAY F~ JULY K2OCT ZSF #3
ZSF #2 N U Id B B ft p B B
60
N U U I S ft
CRAB
40
CRAB 60 40
p S I’
20
20
H A
H A
‘~
l~A6I5TER
PROOUCrUS
GRACILI5
I
flA~ISTER
TMEE
P~QOUCTUS
N U I’ S S ft p S ft H A
50
N U U I B ft
SHRIMP
40
30 20
I
10 0
Pt.ATV DISPAB DAMAE
Jafto
P~.
p B ft H A
BOBEAL
£051
50
30 20 10
p S ft H A
N U
~250 200
150
150
Gall
KVPSIB
STARFISH
100 H A
0
I
MAY
JULY
I
FEB
OCT N U H I S ft
SEA CUCUMBER 12 9
p £ ft
6
I LI I~ FEB
MAY
SO
I
15
0
SOREAL
300
200
3
.10RS
SHRIll’ SPECIES
STARFISH
FEB N U U B B ft
U
~ 11~
PLATY DISPAS - DAJIAE
100 H A
TABI~R
40
I(VPSII
300 250
U
172
SHRIMP
SIIUIIP SPECIES N U Id B
BBACILIS
CRAB SPECIES
CRAB SPECIES
H A
JAY
OCT
I
MAY
I
JLLY
—4
OCT
15
SEA CUCUMBER 12 9
6 3
NOT COIMTED
FEB
MAY
JULY
OCT
Figure 28. Comparison of average otter trawl catches (estimated #Iha) by species and by season between Nisqually ZSF 2 and ZSF 3.
57
DUNGENESS CRAB
Figure 29.
Maps of Bellinghain Bay showing Dungeness crab densities as estimated from beam trawl catches in February, May, July and October 1987.
58 CANCER MAGISTER
BELLJNGHAM BAY
SHELL CONDITION
SHELL CONDITION
20
100 80 60 40 20
• VERY SOFT ~ SOFT
O HARD
~ VERY HARD
SEX 100
I C
140 120
.JLMNILE hAil
uJ U ‘U
40 20 FEB
FEMALES NOT GRAVE
1~iJ~[1j 0
FEB
MAY JAY OCT
J\ f~ IA
60
~ KATCHINB
20J14N
40
10
60
80
100
120
140
60 501
Msle
160
180 200
MAY
8
401 304
—
—
40
50
80
100
120
~m~~LT~fl__
140
160
180 200
JULY
J
6 4 2
I-)
40
60
80
100
120
140
10
10 160
180 200
OCTOBER
,
30
40
15
20
~.
25
50
50 80 100 120 140 160 180 200 CARAPACE WIDTH (mm)
fl. 30
JULY
~1i1._. 10
30 20 10 20
11fl
25
MAY
15
20
60 40
V
0
20
I
r~I
30 20
to 8
I-i n
L~ .1i.
~II
40
...~.
20
is
60 50
U V.
o
~
to
20 -
6 ~ 2
FEBRUARY
40~
2
20
FEFIALE
____
tO1~ U’
C]
~o1~
n
0
5JULY OCT
60T
u~
6 4
SPEIET
0~I! FEB MAY
MAY ~JULY OCT
201
20
P E R C E N T
~t.EDlut’1 ØtLD
DEPTH DISTRIBUTION
Fem~1e
S 4 2
•
80
hALE
FEBRUARY
•
I__.1
SIZE FREQUENCY 10
AGE OF EGGS ~€w “
100-ri
25
30
OCTOBER
w1~~1~iJw=~F1 10
15
20 DEPTH Cm)
25
30
Figure 30. Summary of Dungeness crab depth distribution, size frequency, shell condition sex composition, female reproductive condition and egg age in Bellingham Bay during four seasons of 1987.
59 CANCER PRODUCTUS
BELLINGKAM BAY SEX
• JUVENILE
O HALE
~ FEtIALE
AGE OF EGGS
FEMALES 120 100 80 60 40
U La
0.
20
rLr~J1J1_j FE~
MAY
.IX.Y
120 100
F~
60~ 40~ 20
NOTERAVIDI
it’
PEa
OC1~
MM
j~ FEBRUARY
8 ~1 5 U 4
V
2 CL.
20
40
60
80
100
120
10
P E R C E N T
I
40 20 140
10
160
40
2
20
JULY
10 8
:
15
I.
20
25
140
30
MAY
H
160
15
20
15
20
-
H
25
JULY
25
30
100
IUV’
80
~
60 40 20
~
20
10
40
5u V
2 C— 0
60
80
100
120
140
160
20
40
0 100
OCTOBER
8 j 4
I
100 60
~0 ~ 120
FEMM1I
60
4
80
D
FEBRUARY
6
4050
MALE
80
80
20
OCt
100
8
~0
JULY
NEW MED OLD HATCH SPENT
DEPTh DISTRIBUTION
SIZE FREQUENCY
10
U ~ E~ ~ Q
OCTOBER
80
J I
60 80 100 120 CARAPACE WIDTh (mm)
50 40 20
e 140
160
II 0
IS
H
20 DEPTH
2S
30
Cm)
Figure 31. Summary of Cancer productus depth distribution, size frequency, sex composition, female reproductive condition and egg age in Bellingham Bay during four seasons of 1987.
60 CANCER GRACILIS
BELLINGHAM BAY SEX
• o~
MALE FEMALE
AGE OF EGGS
FEMALES 120
120 100 ~80, ~6O~ ~ 40~ 20
too NOT GRAVID ji GRAVID I
FE~
PlAY
.RLR
80 60 40~ 20-
I
rr~
OLE
• NEW ~ MED 0 OLD ~ HATCNING O SPENI
PlAY
JULY
DEPTH DISTRIBUTION
SIZE FREQUENCY
MALE
FEBRUARY FEMALE
MALE
60
60
80
100
Finn 10
120
FEMALEI
FEBRUARY
80
20 40
C
100
4°
20
OCT
15
20
25
30
MAY
MAY
P E R C E N T
A 40
60
A 80
100
10 8
0
120
JULY J
60
4
40
LA 40
60
80
~JULY
20
AAII 100
F~1~ 10
120
OCTOBER
30
20
80
6 2
IS
100
15
20
100
25
30
OCTOBER
80 60 40
~k
A A/A 40 60 80 100 CARAPACE WIDTH (mm)
__T. 120
IS
20
25
30
Figure 32. Summary of Cancer gradiis depth distribution, size frequency, sex composition, female reproductive condition and egg age in Bellingham Bay during four seasons in 1987.
61
TANNER CRAB
BELLINOHAM BAY
SEX II
S Q
JUVENILE MALE ~ FEl~1ALE
U’
a.
DEPTH DISTRIBUTION
SIZE FREEQIJENCY
S 100, 50
80
FEBRUARY
401
‘~
304 201
U ~
FEMALE
30
40
50
60
70
FEBRUARY
80
90
40 0
100
10
100
P E R C E N T
50 40 30 20 10
20
15
20
~~l5
20
25
I
25
60 40 20
10
20
30
40
50
60
70
80
90
10
100 100
50 40 30 20 10
n
15
30
if 25
30
JULY
80
JULY
25
MAY
80
MAY
0
FEMALE
20
AA~’
V
C
60
MALE
lot
MALE
60 40
.~
20 0
10
20
30
40
50
60
70
80
90
10
100 100
50 40 30 20 10
80
OCTOBER
0
10
20
30
40
AiA~ 50
60
70
CARAPACE WIDTH (mm)
8090100
OCTOBER
60 40 20 10
15
20 DEPTH (m)
30
i
30
Figure 33. Summary of tanner crab, Chionoecetes baird!, depth distribution, size frequency and sex composition in BelHngham Bay during four seasons of 1987.
62
SHRIMP
Figure
34.
Maps of Bellingham Bay showing the densities of coimnercial pandalid shrimp as estimated from beam trawl catches in February, May, July and October 1987.
63
TRITONIA
Figure
35.
Maps of Bellingham Bay showing desities of the nudibranch Tritonia diomedea as estimated from beam trawl catches in February, May, July and October 1987.
64
LUIDIA
Figure
36;
Maps of Bellingham Bay showing densities of the starfish, Luidea foliolata, as estimated from beam trawl catches in February, May, July and October 1987.
MAY
65
BELLINGHAM DISPOSAL SITES BEAM TRAWL SAMPLES
I SOUTH ZSF
NORTH ZSF N U U B B N p E N
80 60 40 20
H A
I
~L.
MAGISTER
N U U B B
700 600
CRAB
H A
H A
20 0 MA6ISTER
N U U I I N
11
n
40
PLATY DISPAR DARAE
.JOBD
Lii BOREAL
p
£
250
BOIl
p B N H A
TANNER
H A PLATY DISPAR DANAE
JORD
BOREAL
Gall
HYPSIN
ShI~IMP SPECIES N U U S I N
STARFISH
200 150
p I I’
100 50
H A
n
250
STARFISH
200 150
100 50 0
FEB
N U U B B N
6RACILIS
p I N
HYPSIN
N H A
-il-I
SHRIMP
S~I~IHP SPECIES N U U S B N
PRODUCTUS
CRAB SPECIES
500
100
CRAB
60
TAMER
GRACILIS
SHRIMP
300 200
80
cRAB SPECIES
400 ~
N U U S I N p I N
PRODIICTUS
FEB E MAY ~I JULY ~ OCT
NAY
JULY
FEB
OCT
TR/TtW/A 50 40
30
N U hi S I I’
20
p I N
10
H A
~1
PER
I
MAY
JULY
OCT
60
TRITON/A
50 40 30
20 l0
I
C FEB
MAT
I JULY
OCT
Figure 37. Comparison of average beam trawl catches (estimated #/ha) by species and by season in the North and South ZSFs in Bellingham Bay.
66 SFEB
C
BELLINGHAM BAY DISPOSAL SITES OTTER TRAWL SAMPLES
SOUTh ZSF
NORTh ZSF 80
H U
p S R
$0
N U U I B N
CRAB
$ S R
60
40 20
CRAB
60 40
p S N
20
H A
H A HASISTER
PRODUCTUS
GRACILIS
— MAGISTER
TA$~R
CRAB SPECIES
N U U B B R
700
p B R
300
H A
100
N
700
~
400
600 500
400
TAMER
PR000CTUS 6RACILIS CRAB SPECIES
1214 1111
SHRIMP
114$
1~
~300 5 200
200
H A PLAT? DISPA1 DANAR
100 0 Pt.ATV DISPAR DAllAS
.305*
250
JOGS
BCREAL
sam
HYPSIR
SHRIMP SPECIES
SHRI~W SPECIES N U
MAY
~ JULY ~OCT
N
o
STARFISH
250
~200
~200
B N
B *
ISO
STARFISH
150 100
I00 N H A
50
H A FEB
N
60
U I B a
SO
~
30
u
MA?
JILT
N
TRiTON/A
60
p
FEB
MA?
ocr
J~L?
rRITON/A
40
~20
~20 H A
o
OCr
10
H A
•1
o~ FEB
MAT
.ALT
OCT
__
10 ________
0
________ •1
,.I
FEB
MA?
t~. .RiL?
OCt
Figure 38. Comparison of average otter trawl catches (estimated #Iha) by species and by season between the North and South ZSFs in Bellingham Bay.
67
GEORGIA STRAIT
Figure
39.
-
APRIL 1987
Maps of the southern Strait of Georgia area showing densities of Dungeness crab, commercial pandalid shrimp, scallops and sea urchins as estimated from beam trawl catches in April 1987.
68
GEORGIA STRAIT
-
OCTOBER1987
DungenessC r& 0:0 • 1-50 • 51—150 •
151—250
•
>250
.9
6
0
.10 •11
0~~~ ~‘
1
2’~
30
NI~
P.t.i IL
Such
Figure
40.
I..
Maps of the southern Strait of Georgia area showing the densities of Dungeness crab, commercial pandalid shrimp, scallops and sea urchins as estimated from beam trawl catches in October 1987.
69
CANCER MAGISTER
—
STRAIT OF GEORGIA
,_jl, , riJJ° SHELL CONDITION
SHELL CONDITION 140
MALE
1 20 w
~
4
FEMALE
~q~~J!~o
100 80 60 40 20
APRIl.
OCl•
APRIL
4
120
OCT
FEMALES
w U U’
a.
APRIL
OCt
DEPTH DISTRIBUTION
SIZE FREQUENCY 10
/
APRIL J U
MALE 100
MALE
80 60 40
P E R C E N T
20
C
FEMALEj
I
ni
30
APRIL
50
100
125
150
200
225
OCTOBER 100
OCTOBER
80 60 40 20 C 0
20
40
60
80
100
120
140
160
CARAPACE WIDTH (mm)
180 200
•
50
100
125 DEPTH
(m)
150
200
225
Figure 41. Summary of Dungeness crab depth distribution, size frequency, shell condition, sex composition, female reproductive condition and egg age in the Strait of Georgia during four seasons of 1987.
Figure
42.
-
APRIL 1987
Maps of Rosario Strait showing the number of commercial panthJLd shrimp, pink scallops and sea urchins caught per 0.1 nautical mile (N.M.) by the rock dredge in April 1987.
ROSARIO STRAIT
0
Figure
43.
Maps of Rosario Strait showing the number of commercial pandalid shrimp, pink scallops and sea urchins caught per 0.1 nautical mile (N.M.) by the rock dredge in October 1987.
ROSAIRO STRAIT- OCTOBER 1987
Figure
44~
-
APRIL 1987
Maps of the Port Townsend region of the Strait of Juan de Fuca showing the densities of commercial pandalid shrimp, pink scallops and sea urchins as estimated from otter trawl catches in April 1987.
PORT TOWNSEND
f\)
Figure
45~
;S.1S%~\
p2500
P,oI.ct
• 0
o\
0
S.
. MCCw4y
.,
.~
.‘
Pi.l,Id..
SmiIh Is.
Maps of the Port Townsend region of the Strait of Juan de Fuca showing the densities of commercial pandalid shrimp, pink scallops and sea urchins as estimated from beam trawl catches in October 1987.
0
1,..
•
• 1501-2500
1-500 501-1500
•
=0
•
o
Pink Scallop
PORT TOWNSEND- OCTOBER 1987
Figure
46.
-
APRIL 1987
Naps of the Port Angeles region of the Strait of Juan de Fuca showing the densities of commercial pandalid shrimp, pink scallops and sea urchins as estimated from beam trawl catches in April 1987.
PORT ANGELES
Figure
47.
-
OCTOBER 1987
Maps of the Port Angeles region of the Strait of Juan de Fuca showing densities of commercial pandalid shrimps pink scallops and sea urchins, as estimated from beam trawl catches in October 1987.
PORT ANGELES
01
76
APPENDIX TABLES
138 132 110 129 116
137
132
108
129
108
2
3
4
5
6
56 73 73 70 71
60
74
73
70
.70
2
3
4
5
6 11 27 51 93 130 104
11
21
42
80
82
44
1OE
20E
40E
80E
80W
40W
Transect #1
55
56
1
ZSF #3
141
End
142
Start
Depth (in)
I-
ZSF #2
Station number
0.35 Sandy Pt.
0.35 Sandy Pt.
1.13 Tatsolo Pt.
1.15 Tatsolo Pt.
1.15 Tatsolo Pt.
145 Tatsolo Pt.
0.95 Treble pt./1.65 Devils lid.
1.05 Treble Pt./1.35 Devils lid.
0.65 Treble Pt./1.25 Devils lid.
1.00 Treble Pt./0.72 Devils Hd.
2.90 McNeil Is./0.62 Treble Pt. Shore
2.50 McNeil Is./0.6O Shore N. of Devils lid.
1.50 S. Ketron Is./0.38 Cole Pt. 1.50 S. Ketron Is./0.38 East Shore
0.60 Ketron Is./0.5O Tatsolo Pt.
0.55 Sandy Pt./O.75 Cole Pt.
0.80 Ketron Is./1.50 Tatsolo Pt.
1.60 McNeil Is./0.75 Ketron Is.
Range markers and distance (N.M.) (at start of net set)
Appendix Table 1. Summary of the Nisqually area station location data.
27874.8/42197.9 27871.0/42198.6
200 50 20
355
340
330
350
340
335
330
335
320
85
15
27881.9/42199.7
27881.4/42200.0
27874.1/42204.8
27874.0/42205.0
27873.7/42205.2
27874.8/42205.4
27897.1/42183.2
27900.2/42182.3
27899.1/42183.9
27904.1/42183. 1
27903.1/42185.4
27902.9/42187.4
27872.0/42202.0
20
10
27877.2/42201.2
200
LORAN C
27882.0/42204.3 27879.4/42202.7
210
(degrees magnetic)
Compass heading
—1
34 H
21
9
20W
‘Ow
27879.6/42195.0 27877.9/42194.3 27876.7/42195.7
60 40 40
0.34 Oro Bay Penin. 0.20 Lyle Pt. Shore 0.15 Base of Dupont Wharf 1.00 Lyle Shore 0.60 Base of..Dupont Wharf
12 41 85 100 107 79 73
43
61
81
110
83
62
43
40N
60N
80N
11 OH
80S
60S
40S
20S
105
21 40
40 20 10
24
40
42
20
10
20N
40N
40S
20S
‘Os
2.15 S. Dupont Shore
2.15 S. Dupont Shore
2.12 S. Dupont/0.89 Shore Anderson Is.
2.35 S. Dupont Shore
2.10 S. Dupont Shore
2.10 S. Dupont Shore
27882.4/42189.8 27884.4/42189.3 27881.0/42186.6 27880.9/42185.8 None
120 120 115 100 100
None
30
0.17 Base Dupont Wharf
11
‘3
27882.6/42189.7
27867.2/42198.2
20
0.17 Base Dupont Wharf
21
17
130
27867.5/42197.9
20
0.17 Base Dupont Wharf
50
H
27867.9/42197.6
15
0.15 Base Dupont Wharf
11
27870.7/42197.5
230
iON
Transect #3
27873.5/42196.2
65
0.47 Base Depont Wharf/1.OO Lyle Pt. Shore
27870.7/42197.2 230
20N
24
13
iON
27880.0/42195.4
27883.0/42199.9
90
170
0.50 Sandy Pt.
27882.4/42199.7
LORAN C
0.36 Oro Bay Penin.
U
0.35 Sandy Pt.
Range markers and distance (N.M.) (at start of net set)
Compass heading (degrees magnetic)
9
Transect #2
End
Depth (m)
Start
Station number
Appendix Table 1, cont’d
-‘I
33 53
67 44 17
43
61
59
43
24
13
40E
60E
60W
40W
20W
low
20 37 43 21 13
22
42
39
23
12
20E
40E
40W
20W
low 59 89 66 61
60
89
66
70
A
B
C
V.
Other Stations
12
13
1OE
Transect #5
19
21
20E
13
12
End
12
Start
Depth (m)
1OE
Transect #4
Station number
Appendix Table 1, cont’d
27893 .5/42 187.5 None None 27898.3/42180.9 27898.8/42180.1 27900.5/42178.4 27899.8/42178.2
280 295 295 45 305 300 315
170 Devils Head
1.70 Devils Head 1.75 Devils Head 0.60 T4 Knob/1.95 Devils Hd./l.67 Treble Pt. 2.10 Devils Dead 0.35 S. T4 Notch
0.42 Lyle Pt./1.42 Dupont Dock Tip/1.lO Tip of South Deck
1.00 S. Shore Knob/2.10 Devils Head
0.60 Devils Hd. Shore/1.85 Treble Pt. Shore
27892 .4/42184.2 27874.7/42191.1
325 80
27906.9/42185.9 35
2.50 McNeil Is.
27911.8/42180.6
27906.5/42186.0 30
2.50 McNeil Is.
95
27905.3/42186.5 50
2.45 McNeil Is.
27904.6/42190.0
27905.4/42187.8 195
2.40 Shore N. of T4 West
10
27898.9/42189.1 210
2.40 Shore N. of T4 West
1.75 McNeil Is. Shore/O.50 Spit N. of Devils Rd
27898.9/42188.2 195
240 Shore N. of T4 West
1.50 Treble Pt./0.70 T4 Knob
27893.8/42187.6
275
LORAN C
1.70 Devils Head
Range markers and distance (N.M.) (at start of net set)
Compass heading (degrees magnetic)
(0
22
30
31
31
27
21
17
11
20W
30W
30M
30E
25E
20E
15E
tOE
17
22
28
31
28
22
15W
20W
25W
30M
25E
20E
11
17
21
27
tON
lSN
20N
25N
Transect #3
12
low
Transect #2
12
Start
28
22
18
12
23
29
31
27
22
16
11
13
18
24
26
31
31
29
22
12
End
Depth (m)
1.0W
Transect #1
Station number
1.5 Edgemoor/2.5 W. Bell. Knob
1.80 Edgenioor/l.85 W. Bell. Knob
2.28 S. Bellingham/l.75 Shore (W. Bell. Knob)
260 S. Bellingham (Edgemoor)/1.50 Nearest Shore
0.75 Governors Pt.
1.54 Governors Pt./0.75 Chuckanut Knob
1.5 Post Pt./3.0 Governors Pt.
1.75 N. Portage Is./2.5 T2 Knob
1.5 N. Portage Is./l.75 T2 Knob
1.5 Brant Pt./1.45 T2 Knob
1.5 N. Portage Is./1.13 T2 Knob
2.38 Governors Pt.
2.38 Governors Pt.
0.50 Chuckanut Knob/O.14 Shore
0.50 Chuckanut Knob/O.20 Shore
2.5 Governors Pt./0.60 “R2”
3.0 Governors Pt./1.8 Post Pt.
2.0 Buoy “RB”/0.30 Pt. Francis Shore/2.85 N. Eliza Is.
2.0 Buoy “RB”/O.22 Pt. Francis Shorel2.85 N. Eliza Is.
2.0 Buoy “RB”/2.85 N. Eliza Is.
Range markers and distance (N.H.) (at start of net set)
Appendix Table 2. Summary of the Bellingham Bay station location data.
80
95
215
215
350
30
295
225
200
210
180
160
160
155
145
25
60
135
140
145
Compass heading (degrees magnetic)
30
27
22
30M
25S
20S
17
22
27
31
15N
20N
25N
30N
29
32
29
28
39
30
29
29
29
29
A
B
C
D
E
F
G
II
I
3
Other Stations
11
iON
Transect #4
31
30
29
30
30
30
41
29
30
33
29
31
27
23
17
11
22
28
31
31
Depth (~‘~ Start End
30N
Station number
Appendix Table 2, cont’d
2.50 Governors Pt./1.85 Chuckanut Knob
1.5 Portage Is./2.75 T2 Knob
2.50 N. Eliza Is./O.70 Pt. Francis Shore
2.5 N. Eliza Is./1.3 Pt. Francis Shore
1.5 Pt. Francis Shore/1.85 N. Eliza Is.
1.0 N. Eliza Is./27O Governors Pt.
1.7 N. Eliza Is./2.U Francis Pt. Shore
2.0 Governors Pt./0.45 Chuckanut Pt.
0.35 Post Pt./2.50 S.W. Marina Breakwater
1.0 Post Pt./2.3 S.W. Marina Breakwater
3.0 Governors Pt./0.85 Post Pt.
0.75 Edgemoor/0.75 Buoy “R2”
0.75 Edgemoor/l.46 S. Ent. to Marina
0.85 Bellingham Shore/LU S. Ent. to Marina
65
220
160
170
175
155
265
325
112
50
90
100
110
115
35
1.5 Governors Pt./2.2 Chuckanut Knob 1.25 Edgemoor/0.80 E. Shore
60
60
85
Compass heading (degrees magnetic)
1.5 Chuckanut Knob? 0.80 Governors Pt.
2.5 Governors Pt./1.42 Chuckanirt Pt.
3.2 Governors Pt./0.85 Buoy “R2”
Range markers and distance (N.M.) (at start of net set)
28828.7/42344.1 28813.0/42342.3 28794.8/42338.7 28802.5/42349. 1 28849.0/42334.2 28774.0/42347.7 28843.8/42348.7 28833.0/42360.1 28832.4/42368.3 28821.1/42378.8
155 160 345 155 60 230 120 270 350 285
5.5 Pt. Rob./6.0 Alden Pt./7.2 Birch Pt. 4.5 Alden Pt./5.2 Savage Pt.! 7.5 Pt. White Horn 2.70 Alden Pt./4.30 Savage Pt. 4.2 Patos Is. (NE Pt.)! 6.2 Pt. White Horn 4.0 Pt. Roberts/8.85 Birch Pt. 2.0 NE Patos Is./5.6 Turnbo Pt. 4.05 Pt. Roberts/6.53 Birch Pt. 5.45 Pt. Roberts!4.70 Birch Pt. 3.42 Birch pt./6.60 Kwomais Pt. 2.20 Birch Pt./2.50 Pt. White Horn
212
225
225
210
150
195
126
100
55
31
3
4
5
6
7
8
9
10
11
2
28816.6/42333.9
140
210
1
Range markers and distance (N.M.) (at start of net set) 4.65 Savage Pt./5.0 Alden Pt.
Depth (m)
Station number LORAN C
Summary of the Point Roberts (Strait of Georgia) Dispersive Site station location data. Compass heading (degrees magnetic)
Appendix Table 3.
1\)
OD
28562.8/42340.4 28553.6/42341.3 28546. 7/42337.1 28540.3/42336.4 28534.4/42333.0 28524.5/42331 .3 28540.2/42329.3 No Signal No Signal No Signal
350 340 345 310 315 320 345 155 160 155
1.1 James Is./1.1 Belle Rock 1.80 Buoy “RB”/l.O Belle Rock 1.0 Burrows Is. Light/2.75 Buoy “RB” 1.0 Burrows Is. Light/1.50 Belle Rock 1.15 Allen Is./2.0 Belle Rock 1.25 “R4” (Will. Rocks)/3.0 Belle Rock 2.0 SW Burrows Is./1.75 Belle Rock 2.0 Burrows Is./0.65 Bird Rock 0.90 S. James Is./090 Belle Rock 0.50 James Is./1.0 Belle Rock
75
52
120
82
74
79
82 72 54 74
3
4
5
6
7
8
9
10
11
‘Tow direction can depend on direction and speed of current.
2
28571.9/42342.1
170
70
1
Range markers and distance (N.M.) (at start of net set) 1.35 Reef Pt./1.70 Fauntleroy (Decatur Is.)
Depth (m)
Station number LORAN C
Summary of the Rosario Strait Dispersive Site station location data. Compass heading1 (degrees iiagnetic)
Appendix Table 4.
Depth (m)
150
115
107
76
124
70
Station number
1
2
3
4
5
6
Appendix Table 5.
3.0 Partridge Pt./3.7 McCurdy Pt.
6.30 Partridge Pt./3.04 Smith Is.
4.22 Partridge Pt./5.OO McCurdy Pt.
6.5 Partridge Pt.! 6.0 N. Protection Is.
7.5 Partridge Pt.! 7.2 N. Protection Is.
7.0 Smith Is./7.O N. Protection Is.
Range markers and distance (N.M.) (at start of net set)
52
310
70
60
80
80
Compass heading (degrees magnetic)
LORAN C
28406.4/42277.4
28466.9/42274.4
28424.1/42271.7
28442.3/42263.2
28458.6/42260.9
28459.9/42253.7
Summary of the Port Townsend Dispersive Site station location data.
OD
130
128
136
133
110
134
1
2
3
4
5
6
None
2.25 Buoy “USN W OR”
2.20 Buoy “PA”/3.19 Tip Ediz Hook
0.22 Buoy “PA”/4.02 Ediz Hook
1.70 Buoy “PA”
2.90 Buoy “PA”/1.88 Buoy “USN W OR”
Range markers and distance (N.H.) (at start of net set)
60
60
255
130
65
80
Compass heading1 (degrees magnetic) LORAN C
28517.5/42195.0
28520.0/42182.5
28515.1/42155.0
28530.0/42145.2
28530.0/42155.0
28540.2/42160.0
Summary of the Port Angeles Dispersive Site station location data.
1Direction of tows can depend on strength and direction of current.
Depth Cm)
Station number
Appendix Table 6.
Cii
OD
(110.140 a) 1 2 3 4 5 8
8TAI1OH
flFA1~ TRAWL
2 3 4 S S
(5540 a)
0±0
0*0
9±16
6±15
TRANsECT #4 1Gm EAST 2Gm EAST 4Cm EAST
0 0 0
19 0 0 0 37 0
37 0 0 0 0 0
TRANSECT #3 1Gm SOUTH 2Gm SOUTH 4Gm SOUTH 4Gm NORTH 2Gm NORTH lOm NORTH
0 19 0
3±11
20±19
AVERAGE (± I SD)
I SD)
37 0 0 0 0 0 0 0 0 0 0
37 37 19 56 19 0 0 0 19 37 O
TRANSECT #2 tOrn SOUTH 2Gm SOUTH 4Gm SOUTh 6Gm SOUTH 6Gm SOUTH 11Gm MIDDLE 6Gm NORTH 0Gm NORTH 4Gm NORtH 2Gm NORTH tOm NORTH
0±0
0±0
AVERAGE (±
0±0
0 0 0 0 0 0
0*0
0 0 0 0 0 .0
JULY
0 0 19
9*23
56 0 0 0 0 0
3±7
0 0 0 19 0 0 0 0 0 0 0
0±0
0 0 0 0 0 0 STATE)N ABORTED DUE 11) W)a~ STATTZN ABORTED DUE TO NOO(8 0 0 0 0 0 0 0 0 0 0 0 0
0 0 0 0 0 0
0*0
0 0 0 0 0 0
0 0 0 0 O 0
0±0
0 0 0 0 0 0
MAY
DL64OENESS CR86
0 0 0 0 0 0
0 0 0
0*0
0 0 0 0 0 0
2±6
0 0 0 0 19 0 0 0 0 0 0
75 75 75
25±19
37±49 169 318 37
56 19 19 37 0 19
42*38
82*110 37 131 0 0 19 37
94 37 75 16 0 0 37 56 0 37 1*2
59±42
12±22 131 208 19 37 19 0 19 19 56 356 37
75 56 19 131
0 0 0 56
0 0 0 0 0*0
56 tO
84±68
72±60 0 IS
187 131 58 0 75 56
18±14
12823 19 225 94 IS 37 37
0 io 0 37 19 19
0 to 0 58 0 0
300 206 ISO
18±19
38 0 38 19 G 0
58±63
38 131 19 0 0 19 19 56 56 94 206
63±42
38 19 112 94
94 19
106±91
37 0 262 94 112 13*
12±15
19 19 0 0 0 37
431 281 356
106±185
487 0 19 19 54 19
69±44
94 56 19 58 189 75 131 131 75 112 56
137±119
318 56 37 243
37 131
412±210
595 562 300 58 562 393
76*96
0 75 0 262 75 56
ROCK CRAB IC. jwo4uck~. • C. gracUl..) P58 MAY JULY OCT
0 0
0±0
0 0 0 0 0 0
0±0
OCT
FSflUATED CATCHES PER HECTARE
P60
—
0 0 0 0 56 0
0 0 0
3*8
0 19 0 0 0 0
9±17
0 0 19 19 0 0 0 56 0 0 0
25±37
94 19 0 0
0 37
56*44
75 19 37 112 0 94
9±23
PEa
0 0 0
16±30
0 75 0 19 0 0
9±13
10 19 0 0 19 37 0 0 0 0 0
50*71
150 0 0 0
19 131
12*23
0 0 19 0 0 56
31±28
0 0 37 75 37 37
318 0 0
25*52
19 0 0 0 0 131
55±106
337 56 0 0 0 165 0 19 0 0 19
197±256
0 0 04 131
674 261
50*105
262 37 0 0 0 0
10±10
tO 0 0 IS 19 0
PANDAUD SHRIMP (ALL SPECIES COMBINED) MAY ~WLY 0 0 0 37 tO 0
19 0 56
36S4~373
0 318 243 880 0 749
244±639
0 262 0 19 37 0 19 169 0 19 2154
400*373
19 112 599 131
974 562
34*42
94 75 0 0 37 0
9±16
OCT
0 56 225 131
0 75 112 131
262 187 19 56 1142 281 0 0 0 37 58
0 19 19 243 637 899
0 0 0 75 431 918
160±241
337 300 19 187 787 56 0 19 0 0 56
08±87
0 19 225 36
150 94
3±8
0 0 0 0 0 19
3±8
19 0 0 0 0 0
JULY
150 412 75
843 37 0
412 56 0
320±479 303±360 237*373
0 0 0 0 1086 712
188*212 185±334
112 506 150 150 637 112 0 0 0 tO 168
234±332 240±230
581 449
6±15
0±0 187 899
0 0 0 0 0 37
SilO
5±16 0 0 0 0 0 0
0 19 0 19 0 0
UAY 37 0 0 0 19 0
FES
SEA CUCUMBER
262 112 0
324±399
0 0 37 449 1011 449
235±536
337 225 94 0 1816 94 0 0 19 0 0
218±147
0 112 225 225
356 393
3±8
0 0 0 0 0 •19
9±16
0 19 0 37 0 0
OCT
225 618 524
47±76
0 0 0 0 187 94
204±129
56 206 316 412 37 75 131 318 112 318 262
286±269
468 712 56 37
112 225
- -
NM NM NM NM NM 187
6*10
19 0 19 0 0 0
19 243 206
172±250
0 0 19 599 356 56
225±195
75 337 655 300 19 56 206 75 94 225 431
493±307
637 843 618 94
19 206 131
112±155
0 0 0 383 169 112
158±147
56 150 431 412 10 56 150 94 56 262 56
422±338
337 1049 393 tO
375 356
212±320
281±461 131 637
0 0 75 150 206 843
22±18
56 19 19 19 19 0
19 19 131 37 281 1198
13±10
0 tO 19 0 IS 19
75 0 0 19 0 0
75 187 37
284±302
0 0 150 768 487 300
186±193
94 375 581 431 56 18 206 112 37 131 0
284±176
337 431 112 56
262 508
356±534
0 0 94 281 356 1404
16±30
STARFISH ( ALL SPECIES COMBINED) FEB MAY JULY OCT
Estimated densities (numbers/hectare) of invertebrate resources in and around each of the PSDDA Phase II proposed disposal areas as calculated from beam trawl catches. N. S. = station not sampled; N. M. = not measured (data not recorded).
AVERAGE (* 1 SD)
TRANSECT #1 lOm EAST 2Gm EAST 40m EAST 6Gm EAST 00 m WEST 4Gm WEST 2Gm WEST tOrn WEST
AVERAGE (* I SD)
2SF #3
AVERAGE (±150)
2SF #2
.nc,mAItv
Appendix Table 7.
~
0±0
0*0
0 0 0 0
5±13
AVERAGE (± 1 SD)
NON.TIIANSECT STATIONS A (60m) 6 (9Cm) C (65m) 0(6Cm)
GRAND AVERAGE (±1 SD)
2±9
0 0 0 0
0±0
0 0 0 0 0 0
5±9
0 19 0 0 0
JULY
1±4
0 0 19 0
0*0
0 0 0 0 0 0
0±0
0 0 0 0 0
OCT
787 487 19 19 56 56 94 112 637
168 94 225 0 0 150 206 56 0
NB. 131 0 19 0 75 140 1536 466
JULY 94 56 37 37 19 37 637 843 150
OCt
208 112 131 56 *9 87 37 19
77±67
75 19 19 19 0 0 0 56
24±28
TRANSECT #3 torn NORTH IOn NORTH 2Cm NORTH 2Cm NORTH SCm NORTH SOn SOlIflI 258 SOUTH SCm SOUTH
AVERAGE (± ISD)
67*42
56±37
AVERAGE(iISD)
131 56 94 19 56 19 94
56 75 56 0 19 112 75
TRANSECT #2 IOn WEST 158 WEST 258 WEST 258 WEST 3OnMIDOLE 258 EAST 258 EAST
49±61
56 19 112 169 19 19 0 0
91*48
112 *50 *50 37 56 56 75
28*26
75 19 37 0 0 56 0 37
13*14
37 0 0 19 19 0 19
100 * 9* 252 ±300 286 * 524 212 ±306
MAY
DUNGENESS CRA.I
19 94 0 94 94
FEB 19 51 37 112 262
MAY
356 356 131 131 75 262
27 ± 48
187 0 19 19 0 0 0 19 30±64
S6 0 0 0 0 O 0 0 7±20
16±2348±98
56 37 0 0 0 19 0
o
19
262 75 0 0 0 0 0
35 ± 52
75 131
o o o
19
.
123±202
94 375 58 19
437±464
1161 843 56 56 131 875
38±73
206 75 19 0 0 0 0 0
35±29
56 75 19 37 56 0 0
111 ± 252
NB. 37 0 19 0 0 23 75 730
300 562 187 805 3446
OCT
51*38
112 75 75 56 0 0 56 37
104±75
112 206 187 0 75 112 37
139 ± 157
167 56 0 56 19 75 75 318 486
OCI•
358*552
730 674 206 0
936*475
1573 1386 281 674 786 916
796±1088
ROCK CRAS • C. g,.cN4i~I -~ M~Y JULY
p,oducW.
74±90
0 337 0 0
112 0 0 0 37 0 0 37 131
o
~C. FEB
71±94
37 75 lB 0
203±109218*123
187 262 94 393 150 131
190*77
94 189 112 300 187
JULY
ROCK CRAB
IC. WoductuI • C. 9racilia)
103±102 89*75
ESTIMATED CATCHES PER HECTARS
3±11
FEB
BEAM TRAWL
AVERAGE(* ISO)
STATION TRANSECT #1 1Cm WEST 2Cm WEST 3Cm WEST 3Cm MIDDLE 3Cm EAST 258 EAST 2Cm EAST 158 EAST 1Cm EAST
BELLIIAGHAM BAY
—
0 0 0 0 0 0
0 0 0 0 0 0
TRANSECT #3 1Cm EAST 2Cm EAST 4Cm EAST 4Cm WEST 2Cm WEST tOrn WEST
—
7±20
2±7
AVERAGE (± 1 SD)
0 0 0 0
0 0 0 56 0
o
0 0 0
EAST WEST WEST WEST WEST
0
6Cm 6Cm 4Cm 2Cm tOrn
MAY
DUHOENESS CRAB
— ~5T1MA~~~
FEB
STA11ON
BEAM TRAWL
Appendix Table 7. Continued.
14±31
0 0 0 0
0±0
0 0 0 0 0 0
0±0
0 0 0 0 0
76±206
38 0 0 0
22*22
38 19 19 0 0 56
199±448
0 0 0 0 1273
0 37 318 543 1199 1292 787 37 955
NB. 837 0 56 189 393 1686 56 624
37 225 5187 131 94 393 131 0 1592
OcT
165*402
0 0 0 0
150±367
0 0 0 0 0 899
173±423
0 19 0 75 1217
OCT
56 94 66 19 2022 37 19
412 449 36 0 75 616 0
75 1348 337 19 56 150 0
19 *9 19 131 599 1461 19 18
431 56 0 616 37 131 916 19
300 37 94 56 0 300 1646 112 681±1138286*616276*343316±549
0 0 94 356 2079 0 37 2864
569*966329*747227±256264±463
112 189 337 2753 466 262 IS
1313±1954 574 ± 509 440 ± 555 974 ±1777
0 19 3984 993 1348 187 37 19 5225
PANDAUD SHRIMP (AI.L SPECIES CONSINSO) ~~59 MAY JULY
24±50
0 37 187 19
6*15
0 0 0 0 0 37
0±0
0 0 0 0 0
FEB
PANDAUD SHRIMP (ALL. SPECIES COMBINED) MAY JULY 0 262 0 75 318
WAY
0 19 56 0
62±153
0 0 0 0 0 375
106j195
0 0 31 0 56 19 0 0 14± 22
14± 16
11±15
21±31 0 O 19 18 37 37 0 0
0 0 0 37 19 19 0
4±8
12±26 0 0 0 56 0 75 19
0 0 0 0 19 0 19 0 0
18 19 94 0
116±190
19 19 487 0 19 150
129±158
0 208 19 38 300
JULY
28 ± 53
0 0 150 19 56 0 0 0
5±9
0 0 19 0 0 19 0
10±15
NB. 0 0 19 37 0 24 0 0
JULY
TFa’TOMA MAY 0 0 0 75 37 0 0 0
o
~
*46±258 135±255
0 0 66 0
103±202
0 0 0 0 112 506
272*345 192±291
112 337 19 19 1049
FBI
SEA CUCLIIBER
12 ± 14
0 19 19 37 0 0 0 19
3±7
0 0 0 0 18 0 0
2*6
0 0 0 0 0 19 0 0 0
134*295
0 0 112 0
44±81
37 19 0 0 0 206
103±104
0 225 0 150 75
OCT
-
221±345
0 1854 487 0
25±41
94 56 0 0 0 0
124±95
169 206 31 0 112
178*311
131 1891 318 0
6±10
0 19 19 0 0 0
89±79
131 16* 38 0 19
767 767 56 0 56 37 112 262 506
N.S. 861 75 150 225 131 445 468 412
506 225 56 112 112 19 56 225 431
OCT
174±255
0 112 449 0
16±22
19 0 56 0 19 0
110±140
56 431 37 19 37
OCT
0 56 131 225 75 1273 618
75 131 131 94 169 2509 543
112 169 112 169 112 1180 599
262 243 206 56 0 56 1124 2822
206 337 150 150 281 56 805 1816 417 ± 641 571 ± 903 475 ± 588 234
318 243 1.69 19 37 75 524 1948
±
150 94 167 225 131 300 356 431 118
348±403340±460522±891 350±405
169 56 375 131 37 1180 487
231±183289*322 346±258194±172
599 262 169 150 37 75 169 468 206
STARFISH (AU. SPECIES COMBINED) FEB MAY JULY
197*23*
NM 860 316 0
NM
NM NM NM NM NM NIl
243±231
281 243 0 19 31
STARFISH (ALL SPECIES COMBINED FEB MAY JULY
OD
56 ± 51
APRIL 0 0 0 0 0 0 0 o 0 0 0
0 ± (1
STATION I 2 3 4 5 4 7 ~ ~ 10 n
AVERAGE (0 150)
—
27± 29
37 37 0 37 75 IS (5 75 0 0
58*34
11 ± 16
0 0 0 0 0 37 37 15 IS 0
41*36
0 37 15 75 IS
OCt
17 ± 32
OCTOIER 0 0 0 0 0 0 0 0 19 54 37
ALL CRAS
0± 0
OCTOBER 0 0 0 0 0 0 0 0 0 0 B
26 ± 56
4± 8
0 0 15 0 0 0 0 0 0 IS
(5±20
37 37 0 0 0
*
c~
41 ± 122
2 ± 6
0 0 0 0 0 15 0 0 0 0
22±50
112 0 0 0 0
JULY
ROCK CRAS MAY
APRIL 0 0 24 I 0 2 2 5 9 2 2 4± 7
71 ± 52
OCTOSER 37 19 0 243 0 15 0 0 94 208 15
9 ±12
OCTOBER 0 2 7 1 1 42 II 9 20 6 4
PANDALID SHRIMP (ALt. SPECIES COMBINED)
0.1 NAUTiCAL MILE TOW.
44 ± 84
0 IS 0 150 0 0 0 0 0 225 0
APRIL
PANDAUD SHRIMP (ALL SPECIES COMBINED)
15 ± 50
2± 6
0 0 0 0 0 0 56 0 0 0
81*39
54 43 19 0 0
~
FF9
ESTIMATED CATCHES PER HECTARE
DL*4GENESS ORAl
—
104 ± 164 104 ± 252 65 ±164
64±34
54 75 87 54 0
~VLY
ESTIMATED CATCHES PER
46 ± 124
0 0 0 0 0 0 0 0 15 375 19
APRIL
1108*11(0 STRAIT—ROCK DREDGE
AVERAGE (± 150) IEXCWC4S FS2CK DF~DG~
STATION I 2 5 4 5(RGCKDREDG~ 4 7(ROCKOREDG~ 8 9 10 II
BEAM TRAWL
45 * 52
AVERAGE(±1SO)
011*940 AVERAGE (*ISD)
—
52 ± 35
15 19 58 0 187 37 56 56 IS 37
NON-TRANSECT STATIONS A (30m) S (30m) • C (SOn) 0 (3Cm) E (40n) F (3Cm) 0 (3Cm) H (SOn) I (3Cm) J (3Cm)
STRAW OP GEORGIA
112 94 IS 75 37 15 56 0 54 is
48±53
AVERAG~(±I3D)
75 10 54 94 37
MM
D4MOENESS CRAS
UnMATED CATCI~S PER HSCTAM
131 $8 0 19 15
—
PH
SLAM TRAWl.
STATION
—
TRANSECT 04 l~.4oRTH lsNoRm NORTH NORTH 3~n NORTH
RILLIMONAM BAY
Appendix Table 7. Continued.
19 ± 54
24 ± 18
56 15 37 37 37 IS 0 15 15 0
86±71
(50 75 185 15 15
OCt 0 281 787 375 150
.1111 V
204 1047 243 112 56
206 555 0 281 412 300 860 506 (87 187
445 0 618 1356 15 3753 375 15 0 3221
0 0 225 75 653 2060 2266 1651 37 262
0 0 0 15 0 0 0 0 0 IS Is
36 ± 74
APRIL 0 0 0 0 0 8 55 149 214 2 0
6 ± 10
APRIL
29 ± 80
OCTOBER 0 243 0 0 (5 0 0 0 0 0 19
.
36 * (36
OCTOBER 0 0 0 2 0 IS 154 215 251 8 0
PINK SCALLOP
SCALLOP
524 ± (257 413 ± 485 493 ± 8(5 552 * 594
1000 ± 829 358 ± 253 987 ±1398 751 ± 938
431 2075 730 356 167 355 1404 (367 2603 487
I068±1214558*4I5315±297337*415
37 225 534 837 555
nay
PANOALID SHRIMP (ALL sP*aB~ cOMIS*0I
0 1724 225 506 2864
n
44 ± 57
APRIL 25 0 12 1 7 35 112 (79 83 23 4
31 ± 74
19 0 0 225 0 37 1 0 0 0 0
APRIL
21 ± 28
34 ± 34
0 31 56 0 0 0 75 37 37 54
22±24
0 0 37 (9 56
FF9
11
j
13 ± 27
10 ± 13
19 0 0 0 0 0 15 0 37 15
11±17
0 0 15 37 0
72 ± 69
30 33 41 84 215 1(8 157 96 13
OCTOBER 0
SEA URCI4NS
19 ± 56
0 0 0 169 0 0 2 0 0 0 0
OCTOBER
SEA LIRCIINS
23
13± 35
0 0 0 19 0 0 0 0 112 0
15±24
0 0 (5 56 0
JULY
TT4TOMA MAY
55 11
2± 6
19 0 0 0 0 0 0 0 0 0
15±20
0 0 37 37 0
OCT
41
0.3 ± 0.4
APRIL 0 0 0 I 0 0 0 0 0 2 0
96 ±160
±
0
54 37 37 56 (31 0 0 0 56 0
III ± 55
0,7
±
(.6
OCTOBER 0 0 0 0 0 0 1 5 0 2 0
STARRSII
( ALL SPECIES COMBINED)
227±528
OCTOBER 0 0 0 0 0 0 I 0 150 281 1610
±
(48 ±
112 169 379 56 131 131 56 94 94 225
209
97
116±75
54 IS 206 75 187
497 335 5 484 208
45
(50 19 150 75 187 (50 (31 75 131 37
281±121
375 160 393 337 150
OCT
STARRSH ( ALL SPECIES COMBINED) 0 0 0 19 0 19 0 37 112 487 187
APRIL
0 37 94 19 0 30±35
220 5 364 259
56 ± 47
75 112 150 31 37 19 0 15 37 75
22±50
112 0 0 0 0
STARRSH (ALL SPECIES COMBINED) II MAY JULY
cx~
a S. N.L Sai.pL.d a a • NM M~.ew.d
ALL. CRAB
0±0
OCTOBER 0 0 0 0 0 0
EWflUATED CATCHES PER HA.
AU. CRAB
0*0
OCTOBER 0 0 0 0 0 0
ESTIMATED CATCNSS PER HA
0±0
—
AVERAGE (± 150)
SEMI TRAWL
APRfl. 0 0 0 0 0 0
—
STATiON 1 2 ~ 4 s 6
PORT ANGELES
0±0
—
AVERAGE 1* 150)
SEAN TRAWL
APRIL 0 0 NB. as. 0 N.B.
—
STATiON 1 2 3 4 5 8
PORT TOWNSEND
Appendix Table 7. Continued.
3499±3332
63±78
28775±29150
PANDAUD SHRIMP (ALL SPECIES COMBINED) APRIL OCTOBER 0 58027 37 85270 10 26482 58 3169 206 6002 0 621
44±47
PANDAUD SHRIMP (ALL SPECIES COMBINED) APRIL OCTOBER 37 318 04 3933 NB. 1798 NB. 9382 0 074 U.s. 4882
2761±1807
APRIL 1236 4326 3577 2096 4651 0
437±760
APRIL 1311 0 NB. NB. 0 U.S.
1323±050
OCTOBER 655 2322 2500 1330 1103 10
PINK SCALLOP
1936±3353
OCTOBER 2172 0 0 8558 0 809
PINK SCALLOP
2260±1128
APRIL 1085 431 2622 1798 3071 3652
$83*2266
APRIL 4000 04 NB. N.S. 58 U.S.
1486±013
OCTOBER 712 803 1854 730 2060 2865
SEA URCIINS
2878i3511
OCTOBER 2070 843 0 8521 lB 5805
sE~ uRCIENS
359± 252
APRIl. 187 500 674 318 375 0
.—.
APRIL. N.M. N.M. N.B. U.S. N.M. NB.
222±04
OCTOBER 262 318 262 160 262 56
S~ARRSH
( ALL SPECIES COMBINED)
206*308
StARASH ( ALL. SPECIES COMBINED) OCTOBER 712 0 0 468 0 56
cx
(0
OTTER TRAWl.
(110.140 se) 1 2 3 4 5 6
0 NB. 0 NB.
0 0 0
TRANSECT #5 4OmWEST,REPI REP2 2OmWEST.REPI REP2
NON-TRANSECT STATION) A(EOm) B(SOm) C (65m)
—
0 6 NB.
FBI
SEAM TRAWL
TRANSECT #1 SOn MIDDLE 305 EAST. REP 1 REP2
STATION
SELLINOHAM SAY
—
0.4±1.7
0 NB. 0 Na 0 NB. 0 NB. 0 Na
TRANSECT IS 20m BOWH.REPI REP2 4OmSOUTH,REPI REP2 6Dm SOUTH,REPI REP2 8OmSOUTh,REPI REP2 11Cm IBDDI.E,REPI REP2
IIr1SDI
0±0
AVEJ1AGE(*ISD)
~flANflAVFRAOi
0 0 0 0 0 0
(53.78 m)
1*3
0 0 0 0 6 0
0±0
0 0 NB.
0 0 0 0
0 0 0 0 0 0 0 0 0 NB.
0±0
0 0 0 0 0 0
0±0
0 0 0 0 0 0
0 0 0 0 0 0
“~~“
0 0 0
0 0 0 0
0 0 0 0 0 0 I 0 0 0
0*0
0 0 0 0 0 0
0*0
OCT
NB. 15 B
MAY
0 23 NB.
JULY
D4#401N156 CRAB
0 8 NB.
OCT
~l*6
0 0 6
23 6 0 0
I 6 0 0 0 0 0 0 0 0
5±9
23 0 0 I 0 0
1.5+3.2
0 0 NB.
0 6 8 0
6 6 0 0 0 0 0 0 0 NB.
1*3
8 0 0 0 0 0
0*0
0 0 0 0 0 0
0 0 NB.
NB. 0 S
0 0 NB.
0 0 0 8 0 0
8±15
6 0 0
8 0 46 15
0 23 23 62 0 23 6 15 0 0
0±0
0 0 0 0 0 0
1.3*3.3
0 6 NB.
ROCK CRAB (C~ ploducbJ. • C. ~r.*2Is) MAY JULY OCT
2+~
0 0 6
23 NB. 15 NB.
0 NB. 0 NB. 0 Na 0 NB. 0 NB.
0±0
0 0 0 0 0 0
0±0
0 0 0 0 0 0
ROCK CRAB (C~ producBIs • C. grac4IIa) MAY JULY OCT
0±0
0 0 0 0 0 0
PSI
WflMATSD CATCIWI PER HECTARS
0±0
0 0 0
0 o 0 0
0 0 0 0 0 0 0 0 0 0
0*0
0 0 0 0 0 0
0±0
0 0 0 0 0 0
JULY
DIMGENESS CRAB
MAY
PU 0 0 0 0 0 0
~
15 0 0
0 0 0 0
8 0 0 0 0 0 6 31 15 15
228*617
1281 SI 15 IS I 0
54+127
0 0 NB.
0 0 0 0
15 0 0 0 0 0 0 77 0 NB.
133*260
649 147 0 0 0 0
6±7
15 8 15 0 0 0
NB. 7690 4548
176 440 NB.
PANDAUD SHRIMP (ALL SPECIES COMBINED) MAY JULY 1243 2308 NB.
FEB
~~-‘
6 62 147
0 Na 0 NB.
0 Na 0 NB. 0 NB. 0 NB. 0 NB.
23*19
0 I 31 54 23 23
25*24
8 8 31 70 38 15
PANDAUD SHRIMP (ALL SPECIES COMBINED) MAY JULY
0±0
FEE 85 0 0 23 8 6
555 643 NB.
OCT
11+21
5 0 0
0 0 0 0
6 59 0 0 0 0 6 6 6 6
17±27
69 0 0 9 25 0
21±33
OCT
23 23 NB.
NB. 0 0
MAY
0 0 NB.
JULY
10±17
0 8 NB.
0 0 0 0
8 15 S 0 6 0 39 38 54 NB.
0±0
0 0 0 0 0 0
14±21
54 0 0 15 0 15
JULY
TAITON~A
21±33
5±6
FEB
85 0 0
0 0 0 0 0 0 8
0 NB. 0 NB.
46 38 31 0 38 23 100 83 83 31
0*0
1*0 0 NB. 15 NB. 0 NB. 0 NB. 0 NB.
0 0 0 0 0 0
4±9
4±9 0 0 0 0 0 0
0 0 0 23 0 0
UAY
SEA CUCLEISER
0 0 0 23 0 0
FEE
0 8 NB.
OCT
25±55
0 15 0
0 0 0 0
54 31 6 6 8 0 255 162 54 62
0±0
0 0 0 0. 0 0
13*15
39 8 0 23 8 0
OCT
0 6 0 8 0 0
4±11
8 0 0
0 0 0 0
0 0 0 38 31 0 0 0 0 0
5±13
0 0 31 0 0 0
1.1±35
0 0 NB.
0 8 0 0
8 15 0 0 0 0 0 0 0 NB.
0±0
0 0 0 0 0 0
0±0
0 0 0 0 0 0
NB. NM. NM.
MAY
23 8 NB.
JULY
( ALL SPECIES COMBINED) N.M N.M. NB.
FE)
8±20
0 83 8
0 NB. 8 NB.
15 NB. 8 N8. 0 NB. 8 NB. 0 NB.
5±8
0 0 12 0 0 15
0±0
0 0 0 0 0 0
39 15 0 8 15 0
16 70 NB.
OCt
21±4±
0 247 0
0 0 0 0
15 IS 31 54 39 23 31 8 8 0
9±12
0 0 8 0 15 31
13±14
ARFISH ( ALL SPECIES COMBINED) MAY JULY OCT
3±4
FEB
Estimated densities (numbers/hectare) of invertebrate resources in and around each of the PSDDA Phase II proposed disposal areas as calculated from otter trawl catches. N. S. = station not sampled; N. M. = not measured (data not recorded); REP = replicate tows.
ESTIMATED CATCHES PEl~ HECTAJIS
FE)
—
I 2 3 4 5 6
ZIP 52
AVERAOE(±18D)
2SF 82
—
STATION
NISOUAU.Y
Appendix Table 8.
0
SAY
—
050
APRIL 0 0 0 0 0 0
—
6± 14
APRIL 0 0 0 NB. 0 NB. 0 0 0 39 3*
SIAM TRAWL
SIAM TRAWL
AVERAGE (2 150)
STATION I 2 3 4 5 8
—
Ii ISO)
PORT TOWNISNO
AVERAOI
STAflON I 2 S 4 5 I 7 S 9 10 II
STRAIT OP 010101*
B + 18
0 5 23 0 0 $5 8 0 NB
N014-TRANSBCT STA11OI A (Born) B (Born) o (3~n$ 0 (AIm) F (3Im) o ~ H (BOrn) I (3Cm) .1 (3Cm)
I,tRflt
NB.
TRANSECT 54 Born NORTH
~.Arn ,-...,.-,~ •VVRAflY .—,.,.-.—
NB. NB.
TRANSECT 53 ~mNQRTH Born NORTH
Pfl~
SIAM TRAWl.
31 Nt 15 NB. 8 NB.
—
25m BAIT, IWPI R5P2 2O~EA8T,IEP1 REP2 tIm SAST,IWPI REP2
ITAIIOM
1.UNSIIA
20 + 22
15 23 NB. 8 5 $ 0 15 8
31
0 0
46 23 NB. NB. 77 54
0 0 0 0 0 0 0 0 NB. 0±0
8± 7
NB.
NB. NB.
0 NB. 0 NB. 0 Nt
ALL CRAB 0 0 0 0 0 0
HA
0±0
OCT
ISTIIIATED CATCHES Pt I
3± 10
0 0 0 NB. 0 NB. 0 0 0 3* 0
OCT
406±491
APRIL 0 *23 247 710 86 1287
PANDAUD SHRIMP (ALL SPICIES COMIS4ID)
295±S46
APRIL 55 0 0 NB. 0 NB. 216 286 1027 518 15
1.4±4.0
0 0 NB. 0 0 0 0 0 0
0
0 0
$5 I N.B. NB. 0 0
PANDAUD SHRIMP (ALL ~ia~s
0,5±1.3
0 0 0 0 0 0 0 0 0
NB.
NB. NB.
0 0 0 S 0 0
6818*5112
OCT 14584 2549 8949 3878 1027 962$
67 ± II
0 9 15 os. 117 n.s. $17 46 247 55 0
OCT
•~.A —— —
0 5 0 8 0 0 0 0 5
5
5 S
0 I NB. NB. $5 32
ROCK CRAS (C. pIAthIAEM • C. ~a.1I~ .rm MAY JULY OCT
0 0 S $ 0 0 0 0 23
0
I I
0 5 N.5. ILB. 15 18
411LY~OCrz
ESTiMATED CATCHES FIR IMCTAM
8 + 8
0 31 15 0 ,0 S 23 15 8
NB.
NB. NB.
0 0 0 0 5 I
~AY
OUNOINSIS CMI
SIflMATID CATCISS PSI NICTAM
DUNOSI4ISS CPUS
—
—
Appendix Table 8. Continued.
2022 4405 142$ 563 8485 5579 6254 340 175
NB.
NB. NB.
2370 1031 0 100 0 0
OCT 394 262 0 548 9 82 212 ± ~7
~O’~iáI
PINK SCALLOP
0±0
0 0 0 NB. 0 NB. 0 0 0 0 0
OCT
388+588
888*1628
APRIL 31 0 9 255 185 0
0±0
APRIL 0 0 0 NB. 0 NB. 0 0 0 0 0
203 257 453 577 555 3088 46 15 950
257
335 592
764 514 NB. NB. 47 85
OCT
347 0 NB. 2895 5003 510 54 0 3930
1713
394 20$
lOIS 0 N.B. NB. 0 .0
SCALLOP
19(2±J4fV3(9~13U~4
5474 1919 278 448 III 1883 $191 *550 NI.
NB.
NB. NB.
II NB. 77 NB. 0 NB.
FIB
PANDAUD SHRIMP (ALL SPICIIS COMSi~I7~ MAY JULY
125±108
APRJL 43 15 9 2*8 139 278
I ± 18
APR I. 0 0 0 NB. 0 NB. 55 0 0 0 0
4 ± 10
IS ill
0 0 NB. 0 0 0 0 15 15
0
0 0
0 0 N.S. NB. 0 0
SEA UIICIINS
ISA URCISNI
0 0 0 0 8 8 5 39 0
NB.
NB. NB.
0 0 0 0 0 0
JULY
.
1.8 ± 5.0
TRITONM MAY
0 8 46 0 I • 31 39 NB.
NB.
NB. NB.
45 NI. 0 NB. 0 NB.
PEa
135 ± 170
OCT 0 108 $5 432 0 255
252 75
OCT 0 0 0 NB. 0 NB. 225 0 0 0 0
659
0 31 0 0 S 0 0 0 0.
$5
8 8
23 0 NB. NB. 0 0
OCT
55 ± ill
o o 0 NB. 0 NB. 339 o 46 24 58
STARFISH ALL SPECIES COMBINED) APRIL ocr N.M. N.M. N.M. N.M. N.M. N. U. N.M. N.M. N.M. . N.M. N.M. N.M.
(
23± 50
APRIL 0 0 0 NB. 0 NB. 0 0 24 154 31
ocr
22±21
28±29
15
8 39
39 31 3$ 0 0 0
‘B
62 B
23 0 NB. NB. 8 39
tV~T
0 0 NB. 105 54 23 15 39 62
39
0 54
5 8 NB. NB. 23 15
.1111 V
STARFISH ALL SPECIES COMBINED)
~
-“
(
N.M. N.M. N.M. N.M N.M. N.M. N.M. N.M N.M.
NB. NIL N.M N.M N.M N.M. N.M N.M N.M NB.
NB.
N.B. NB.
N.M. NM. NM. NM. N.M. NM
N.M NB. N.M. NB. N.M. NB. NB. NB.
MAY
STARFISH (ALL SPECIIS COUSINID FEB
(0
—
N. S. • Not S~pbd N. U. • Nat M.a.uN~ IIEP • RIØcab
—
0± 0
APRIL 0 0 0 0 0 0
BEAM TRAWL
AVERAGE (± 180)
STAflON I 2 3 4 5 6
PORT ANGELES
ALL CRAJ
0±0
0 0 0 0 0 0
HA.
OCT
ES11MATED CATCHES PER
Appendix Table 8. Continued.
PANDAUD SHRIMP (ALL SPECIES COMBINED)
36 ±46
APRIL 0 31 0 62 117 0 2329*1295
OCT 3915 2547 3058 2934 760 740 54 * 65
APRIL 178 9 39 39 62 0
P51K SCALLOP
42 ± 35
9 39 46 24 108 24
OCT
81 ± 50
APRI~ 46 31 132 70 55 134
SEA URC~INS 9
83 ±
64
178 46 132 93
OCT
31 ± 32
51 ± 25
STARFISH ( ALL SPECIES COMBINED) APRIL OCt 31 39 24 39 15 55 93 70 24 88 0 15
(0