CCAMLR

The accuracy of correction factors estimated to compensate the digestion and loss through the gastrointestinal tract of the otoliths of fish represented in pellets of the Antarctic Shag Phalacrocorax bransfieldensis was tested at two localities of the South Shetland Islands. F or such purpose, the results from the analysis of 226 and 115 pellets collected at Harmony Point and at Duthoit Point, respectively, throughout the breeding season were compensated with the mentioned factors. The estimations indicated that the daily food intake increased from November to January (pre-laying to late-rearing) and slightly decreased in February. These estimations, in general, are in line with those previously obtained for other colonies and/or shags by different methods, which suggests that the use pellets is an acceptable method to quantify the diet of the Antarctic Shag.

The diet of juvenile and non-breeding male Antarctic fur seals Arctocephalus gazella was investigated at Harmony Point, Nelson Island, South Shetland Islands, by the analysis of 18 and 33 scats collected during the 1995/96 and 1996/97 summer seasons respectively. Overall, fish were the most frequent prey (74,5%) and predominated by mass (54,4%), whereas krill did by number (94.2%). This pattern coincides well with the observed in 1996/97, but in 1995/96 krill was the most important prey also by mass (50.2%). The importance of the remaining taxa represented in the samples (octopods, hyperiids and bivalves) was negligible. Among fish, Myctophiids represented 85 .2% of the fish mass, being Gymnoscopelus nicholsi and Electrona antarctica the main prey. These two species also predominated in 1996/97, whereas Cryodraco antarcticus and Gobionotothen gibberifrons did in 1995/96. The importance of the Myctophiids as prey of the Antarctic fur seal is discussed.

The diet of the Antarctic petrel Thalassoica antarctica was studied during two years at Svarthamaren, an inland colony situated in Dronning Maud Land, Antarctica and in the pack-ice outside Svarthamaren. The analyses showed that the most important food (wet weight) at Svarthamaren was Crustaceans (68%), followed by fish (29%) and squid (3%), whereas individuals collected in the pack ice took mostly fish (95%), followed by Crustaceans (5%). The prey composition and length found in this study is comparable to what is found in other diet studies. Estimates of food consumption for birds breeding at Svarthamaren (c. 250,000 pairs) indicate that the take approximately 6,600 tons of Crustaceans, 2,600 tons of fish and 485 tons of squid during the breeding season. Furthermore, their annual consumption is estimated to 34,800 tons of Crustaceans, 13,800 tons of fish, and 2,600 tons of squid. Satellite telemetry studies indicate at Antarctic petrels from Svarthamaren may fly more than 3,000 km during one foraging trip and may thus, cover a huge ocean area.

A study on the breeding biology and diet of Pintado Petrels Daption capense was conducted at Nyrøysa, Bouvetøya, South Atlantic, from December 1996 to February 1997. Overall breeding success for the total 300 pairs of breeding Pintado Petrels at Nyrøysa was 59 %. Three study colonies were marked out and monitored intensively; in one colony overall breeding success was only 4 % owing to predation by Sub-Antarctic Skuas Catharacta antarctica on unattended chicks, but in another colony success was 85 %. Rates of failure were higher during the chick stage than in the egg stage for both of these two study colonies. The mean hatching date in these colonies was 11 January, and the first and last hatching 6 and 18 January respectively. The mean period for which chicks were permanently attended by parents (guard period) was 14 days. The length of the guard period was negatively related to the date of hatching (expressed as the number of days passed since the first egg had hatched i.e. 6 January). Growth of chicks in the third study colony was similar to that recorded for other populations of Pintado Petrel, as was the diet of chick-rearing adults - dominated by euphasiids, especially krill Euphausia superba. Whole female krill occurred more frequently than male krill in the diets of chick-rearing Pintado Petrels at Nyrøysa, and were larger. It is estimated that during the nestling stage the entire Bouvet0ya population of Pintado Petrel chicks consumes 6 500kg krill.

Acoustic surveys in the vicinity of the sub-Antarctic island of South Georgia revealed the existence of a number of horizontally extensive yet vertically discrete scattering layers in the upper 250 m of the water column. These layers were fished with a LonghurstHardy plankton recorder (LHPR) and a multiple-opening 8 m2 rectangular mid-water trawl (RMT8). Analysis of catches suggested that each scattering layer was composed predominantly of a single species of either the euphausiids Euphausia frigida or Thysanöessa macrura, the hyperiid amphipod Themisto gaudichaudii, or the eucalaniid copepod Rhincalanus gigas. Instrumentation on the nets allowed their trajectories to be reconstructed precisely, and thus catch data to be related directly to the corresponding acoustic signals. Discriminant function analysis of differences between mean volume backscattering strength at 38, 120 and 200 kHz separated echoes originating from each of the dominant scattering layers, and other signals identified as originating from Antarctic krill Euphausia superba, with an overall correct classification rate of 77%. We therefore demonstrate that with the use of echo intensity data alone, gathered using hardware commonly employed for fishery acoustics, it is possible to discriminate in situ between several zooplanktonic taxa, taxa which in some instances exhibit similar gross morphological characteristics and have overlapping length-frequency distributions. Acoustic signals from the mysid Antarctomysis maxima could additionally be discriminated once information on target distribution was considered, highlighting the value of incorporating multiple descriptors of echo characteristics into signal identification procedures. The ability to discriminate acoustically between zooplankton taxa could usefully be applied to provide improved acoustic estimates of species abundance, and to enhance field studies of zooplankton ecology, distribution and species interactions.