Conclusions: Seabird Counts (October 1997)

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Presentation transcript:

Conclusions: Seabird Counts (October 1997) During many of the cruises seabird were counted from the bridge of the vessel while transiting between stations on the Seward Line. This plot shows an example of the cross-shelf distribution of seabirds during October 1997. The pulse of birds within the ACC and inshore of the frontal boundary (inside km 20) consisted primarily of surface-feeding Northern Fulmars and diving White-winged Scoters; most of the density consisted of one flock of scoters. The concentration of birds between km 25 and 75 occurred in the frontal zone separating the Alaska Coastal Current from shelf water and consisted primarily of deep-diving Common Murres and secondarily of surface-feeding Northern Fulmars. Fisheries data from October 1998 suggest that several species of fishes concentrate in this region at this time of the year. The third concentration of birds occurred between km 100 and 160, and consisted of a congregation of surface-feeding Fork-tailed Storm-Petrels (and secondarily Northern Fulmars) in the vicinity of the shelf-break front, where they presumably were feeding in microscale convergences and divergences. A smaller number of these two species also occurred between km 175 and 225. Seabird Counts (October 1997) Interannual Differences: Preliminary Indication May 1999 May 1998 Temperature - Salinity May 1998 May 1999 Calanoids CalVETs May 1998 May 1999 May 1998 May 1999 Euphausiids MOCNESS May 1999 May 1998 Calanoids MOCNESS 1) Salinities above the pycnocline were substantially higher in May 1999 than in May 1998. Temperatures were lower in 1999 relative to 1998. 2) Substantial intrusion of oceanic water was observed over the shelf in May 1999. Note the decline in salinity in the upper 20 m between km 150 and km 75. 3) Neocalanus biomass in CalVET samples was significantly higher in 1998 than in 1999 over much of the Seward Line. 4) Neocalanus plumchrus and N. flemingeri biomass in MOCNESS samples was higher in May 1998. Lower Neocalanus biomass was observed in the oceanic regime in 1999. 5) Euphausiid abundance was higher in May 1999 than in May 1998, particularly in the oceanic regime. 6) Euphausiid dry weight biomass per unit carapace length was higher in 1999 samples. 7) Processing of the 1999 zooplankton samples is ongoing. Final evaluation of any differences between years will be made when the lab work and data analyses are completed. Conclusions: 1) The northern Gulf of Alaska zooplankton assemblage consists of two major communities: a shelf community dominated by Pseudocalanus spp. and an oceanic community dominated by Neocalanus spp. and Eucalanus bungii. 2) Zooplankton biomass peaks in May or June and is dominated by the large oceanic copepods. Populations peak in June or July and are dominated by the smaller species (Pseudocalanus and Oithona). 3) When distinct zooplankton communities occur along the Seward Line, they are separated by a salinity front dividing the oceanic regime from the shelf community. 4) The northern Gulf of Alaska shelf is a very dynamic system. Rapid cross-shelf and along-shelf flow can modify the abundance, distribution and species composition of the major zooplankton taxa in periods of days to weeks. When the front dividing the oceanic and shelf regime is absent, the zooplankton can be dominated by shelf or oceanic taxa, depending on the origins of the water mass occupying the shelf. Preliminary satellite data suggest that mesoscale eddies may strongly influence shelf circulation (Okkonen, personal communication) and consequently, zooplankton abundance, species composition and distribution. 5) Pink salmon are distributed primarily along the inner shelf. The prey taxa are minor constituents of the zooplankton samples, suggesting high prey selectivity. Acoustic data indicate the presence of major subsurface fish targets. Target identification and verification will be essential to evaluating the effect of these fish on the zooplankton community (Process studies). 6) The long-term observation program is just beginning. As this data set grows, the accumulating information will permit us to identify the magnitude, scale and period of changes in the physical regime and associated zooplankton community. 7) Given the dynamic nature of the northern Gulf of Alaska shelf environment, mesoscale studies will be critical to evaluating the observed changes in the physical regime and the zooplankton community observed by the long-term observation program.