In accordance with CM 21‐03, Annex 21‐03 A, attached are the net diagram and marine mammal exclusion device diagram to be used in conjunction with the online notifications for the krill fishery in the 2015/16 fishing season submitted for the Ukrainian vessel: More Sodruzhestva.

At WG EMM-2013 the Working Group agreed that it would be useful to have a consolidated summary of information related to the krill fishery in a similar format to the fishery reports that are completed for finfish fisheries in WG-FSA (www.ccamlr.org/node/75667).

The Secretariat agreed to coordinate the preparation of a draft krill fishery report for consideration at WG EMM-14 that would be similar in content to a finfish Fishery Report.

Upon the recommendations from WG EMM-14 the report includes the same information provided in the previous report (i.e. an introduction on the background of the fishery, an inventory of catch and SISO data, including incidental mortality of marine mammals and seabirds as well as the CCAMLR approach to management of the krill fishery) with the addition of monthly catch maps for the last complete seasons (2014) and the current incomplete season (2015), an inventory of observer data effort since 2011 and a comparison bycatch occurrence in C1 and SISO data.

RV Tangaroa carried out a 42-day research voyage to the Ross Sea from 29 January to 11 March 2015. The main purpose of the New Zealand-Australia Antarctic Ecosystems Voyage (TAN1502) was to undertake ecological studies of Ross Sea marine foodwebs of importance to top predators. The work was centred on the feeding areas of cetaceans, primarily blue whales and humpback whales, and in the Ross Sea slope area, which is the main fishing ground for the Ross Sea toothfish fishery. Whales were located using passive acoustics and visual observations. Observations of prey species were collected with multifrequency echosounders with associated midwater and demersal trawling. Associated oceanographic and atmospheric observations were made while underway. Samples of prey species and whale tissue (from biopsy) were collected for trophic (stable isotope) studies. Weather conditions during the voyage were excellent and all five science objectives were successfully completed. The voyage was supported by funding from Antarctica New Zealand (ANZ), the New Zealand Ministry for Business Innovation and Employment (MBIE), Australian Antarctic Division (AAD), and the National Institute of Water and Atmospheric Research Limited (NIWA).

In this paper, we develop a candidate management system for the krill fishery suitable for achieving objectives for krill and its predators in local areas. We also indicate how this management system can be made operational in the early phases of a fishery in a local area, which can then be enhanced as the fishery develops, including testing future management procedures and in adapting them to a changing ecosystem. A local area decision rule is proposed for using krill biomass density and recruitment strength in a given year to determine an adjustment of the long-term annual catch for the area in the following year. This decision rule is designed to keep the probabilities of low reproductive performance by predators at acceptable levels in the long term. The process for undertaking the assessment and its application is demonstrated.

Vessels operating in the krill fishery in CCAMLR’s Convention Area are required to directly estimate the green weight of krill caught (Conservation Measure 21-03, Annex B). This requirements was introduced for the 2012/13 seasons, and the estimation methods were revised at WG-EMM-13 and WG-EMM-14. Estimates of green weight and parameter values are reported in each vessel’s haul-by-haul catch and effort data (C1 data).

Vessels fishing in 2014/15 used five methods for the direct estimation of the green weight of krill caught: codend volume, holding tank volume, flow meter (method 2), flow scale and meal conversion.

This paper provides a preliminary summary of the data reported so far in 2014/15 (to May 2015).

Annual acoustic trawl surveys for krill monitoring have been carried out by the Institute of Marine research, Norway near the South Orkney Islands since 2011. The survey has been conducted early in the fishing season (January/February), using two different krill fishing vessels as platforms. The vessels were equipped with similar Simrad echo sounder systems suitable for quantitative assessments, but the frequencies operated varied between vessels and years. In addition, the survey coverage has varied between years in particular due to ice. In order to allow for comparison of distribution and abundance of krill near the South Orkneys among years, we here attempt to generate a coherent series of krill density estimates from the 5 years of surveys. We follow the CCAMLR protocol for biomass estimation as far as practically possible, given that we work with unconventional sets of frequencies for target strength estimation and target identification. In order to avoid variability due to differences in coverage, we also define a stratum within the survey area on the north side of the islands with full coverage in all years except 2013. The results show that except from the year 2015, krill densities were high, in the range 100-300 g/m² based on the 120 kHz recordings, and a total estimated biomass of ca. 8 million tons of krill within the stratum in the peak year 2014. There were also consistently higher values of acoustic backscatter on the north side of the islands where the fisheries occur, than on the south side. Values were particularly high in the north-west shelf area associated with underwater canyons. In 2012, and particularly in 2015, low proportions of the acoustic backscatter were allocated to krill. The low proportions are probably caused by shortcomings in the krill identification techniques when other pairs of frequencies than combinations of 38, 120 and 200 kHz are used.