96 PHYTOPLANKTON COMMUNITY STRUCTURE ON THE FAROE SHELF Fig. 1. Bottom topography and main features ofthe flow field in the upper layers around the Faroes and on the Faroe Shelf. (Based on Hansen, 1992 and Hansen etal., 1994) med the Modified North Atlantic Water (MNAW) (Fig. 1). These hydrographical circumstances cause quite different environmental condi- tions for the phytoplankton on the shelf compared to the outer areas. Inside the tidal front, the phytoplankton is relatively well isolated from the outer area with the water column well-mixed throughout the sum- mer. Outside the tidal front, the hydrograpi- cal conditions are. typically oceanic with stratification of the water column during summer due to the development of a ther- mocline. The Faroe Shelf water, therefore, has its own plankton ecosystem, separated from the surrounding area. It has its own phyto- plankton community which is affected by quite different hydrographical, chemical and light conditions than the phytoplankton in the area outside the tidal front. While the hydrography on the Faroe Shelf is relatively well described (Hansen, 1992; Hansen et al., 1994), no description of the phytoplankton community has been given. The aim of this paper is to describe the community on the Faroe Shelf in 1995 and to relate it to its hydrographical and chemical environment. Material and methods The study was conducted on 5 cruises from April to November 1995, with the Faroese Research vessel „Magnus Heinason”. Sam- ple collection and measurements were car- ried out of hydrography, nutrients, fluores- cence, chlorophyll a and phytoplankton. In addition, samples for nutrient analysis and phytoplankton were collected from a moni- toring station marked »S« on Fig. 5. This water was pumped through an underwater tunnel (0.8 m in diameter) from about 18 meters depth in an area with strong tidal currents and the samples were collected with 3 or 4 days intervals during the period May-December 1995. On the research vessel the temperature and salinity (and hence the density) was in April 1995 measured with a EG&G Mark III CTD and from May 1995 and the rest of 1995 they were measured with a Seabird Electronics SBE911 + CTD. Both instru- ments were equipped with a rosette samp- ler. Water samples were collected with Niskin bottles from the CTD rosette. The samples for analysis of nitrate and silicate were preserved with 3 drops of chloroform per 25 ml of sample immediately after sampling. Normally, they were stored in a refrigerator and analysed in the laboratory 3-15 days after sampling. However, in

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