Hostname: page-component-cd9895bd7-gvvz8 Total loading time: 0 Render date: 2024-12-26T19:02:13.446Z Has data issue: false hasContentIssue false

The phytoplankton ecology of the Firth of Clyde sea-lochs Striven and Fyne

Published online by Cambridge University Press:  05 December 2011

P. Tett
Affiliation:
Scottish Marine Biological Association, Dunstaffnage Marine Research Laboratory, P.O. Box 3, Oban,Argyll PA34 4AD, Scotland
R. Gowen
Affiliation:
Scottish Marine Biological Association, Dunstaffnage Marine Research Laboratory, P.O. Box 3, Oban,Argyll PA34 4AD, Scotland
B. Grantham
Affiliation:
Scottish Marine Biological Association, Dunstaffnage Marine Research Laboratory, P.O. Box 3, Oban,Argyll PA34 4AD, Scotland
K. Jones
Affiliation:
Scottish Marine Biological Association, Dunstaffnage Marine Research Laboratory, P.O. Box 3, Oban,Argyll PA34 4AD, Scotland
B. S. Miller
Affiliation:
Clyde River Purification Board, Rivers House, Murray Road, East Kilbride, Scotland
Get access

Synopsis

Lochs Fyne and Striven are deep-silled fjords opening into the northern Firth of Clyde. They receive relatively little freshwater from local runoff, have a relatively low rate of tidal exchange, and undergo periods of deep water stagnation. Both contain fish farms which have lost stock because of phytoplankton blooms. Loch Striven was investigated in detail in 1980. Observations are also reported for 1979 and 1981, and for Loch Fyne from 1980–1982. Most stratification in Striven is due to salinity layering, but most of the freshwater in the loch probably originates in the Clyde Estuary and is associated with high concentrations of nitrate. Typical phytoplankton biomasses in Striven are the same as those in the western seaboard Loch Creran, but maxima exceed those in Creran. In addition to a red tide of Gyrodinium aureolum in September, 1980, three periods of high biomass seem to be a regular feature of the phytoplankton calendar in Striven. The spring increase takes place in March or early April, is dominated by the diatom Skeletonema costalum, and probably depends on the stabilizing effects of reduced near-surface salinities. A summer flourishing of Leptocylindrus danicus and dinoflagellates is also associated with near-surface salinity layering. A late spring bloom of diatoms, dinoflagellates and small flagellates, some ichthyotoxic, appears to be related to the occurrence of thermohaline stratification and near-surface nutrient depletion; on some occasions lochhead upwelling may also have been involved. Insofar as data are available, the ecology of phytoplankton in Loch Fyne appears similar to that in Loch Striven.

Type
Research Article
Copyright
Copyright © Royal Society of Edinburgh 1986

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Boney, A. D. 1986. Seasonal studies on the phytoplankton and primary production in the inner Firth of Clyde. Proceedings of the Royal Society of Edinburgh 90B, 203222.Google Scholar
CRPB. 1976. Water Quality-a Baseline Report. East Kilbride: Clyde River Purification Board.Google Scholar
CRPB 1981. Sixth Annual Report.East Kilbride: Clyde River Purification Board.Google Scholar
Gowen, R., Lewis, J. & Bullock, A. M. 1982. A flagellate bloom and associated mortalities of farmed trout and salmon in Upper Loch Fyne.Oban: Scottish Marine Biological Association, Internal Report 71.Google Scholar
Hannah, F. J. & Boney, A. D. 1983. Nanophytoplankton in the Firth of Clyde, Scotland: seasonal abundance, carbon fixation and species composition. Journal of Experimental Marine Biology and Ecology 67, 105147.CrossRefGoogle Scholar
Hendey, N. I. 1974. A revised check-list of British marine diatoms. Journal of the Marine Biological Association of the United Kingdom 54, 277300.CrossRefGoogle Scholar
Jones, K. J. 1979. Studies on nutrient levels and phytoplankton growth in a Scottish sea loch. Ph.D. thesis, University of Strathclyde.Google Scholar
Jones, K. J., Cabecadas, L., Gowen, R., Robertson, N. & Tett, P. 1981. The distribution of phytoplankton and nutrients in relation to the hydrography of Loch Fyne and its approaches: a report of a cruise by M.V., Arvor, 112 September, 1981.Oban: Scottish Marine Biological Association, Internal Report 51.Google Scholar
Jones, K. J., Ayres, P., Bullock, A. M., Roberts, R. J. & Tett, P. 1982. A red tide of Gyrodinium aureolum in sea lochs of the Firth of Clyde and associated mortality of pond-reared salmon. Journal of the Marine Biological Association of the United Kingdom 62, 771782.CrossRefGoogle Scholar
Landless, P. J. & Edwards, A. 1976. Economical ways of assessing hydrography for fish farms. Aquaculture 8, 2943.Google Scholar
Mackay, D. W. & Halcrow, W. 1976. The distribution of nutrients in relation to water movements in the Firth of Clyde. In Freshwater on the Sea, eds. Skreslet, S., Leinebo, R., Matthews, J. B. L. & Sakshaug, E., pp. 109117, Oslo: Association of Norwegian Oceanographers.Google Scholar
Mackay, D. W. & Leatherland, T. M. 1976. Chemical processes in an estuary receiving major inputs of industrial and domestic waste. In Estuarine Chemistry, eds. Burton, J. D. & Liss, P. S., pp. 185218. London: Academic Press.Google Scholar
Marshall, S. M. & Orr, A. P. 1927. The relation of the plankton to some physical and chemical factors in the Clyde Sea Area. Journal of the Marine Biological Association of the United Kingdom 14, 837868.CrossRefGoogle Scholar
Marshall, S. M. & Orr, A. P. 1928. The photosynthesis of diatom cultures in the sea. Journal of the Marine Biological Association of the United Kingdom 15, 321360.Google Scholar
Marshall, S. M. & Orr, A. P. 1930. A study of the spring diatom increase in Loch Striven. Journal of the Marine Biological Association of the United Kingdom 16, 853878.Google Scholar
Mill, H. R. 1891. The Clyde Sea Area. Transactions of the Royal Society of Edinburgh 36, 641729; 38, 1161.CrossRefGoogle Scholar
Parke, M. & Dixon, P. S. 1976. Check-list of British marine algae-third revision. Journal of the Marine Biological Association of the United Kingdom 56, 527594.CrossRefGoogle Scholar
Strickland, J. D. H. & Parsons, T. R. 1972. A practical handbook of seawater analysis, 2nd edition. Bulletin of the Fisheries Research Board of Canada 167.Google Scholar
Tett, P. 1973. The use of log-normal statistics to describe phytoplankton populations from the Firth of Lome area. Journal of Experimental Marine Biology and Ecology 11, 121136.CrossRefGoogle Scholar
Tett, P. (ed.) 1980. Phytoplankton and the fish kills in Loch Striven. Oban: Scottish Marine Biological Association, Internal Report 25.Google Scholar
Tett, P. 1986. Physical exchange and the dynamics of phytoplankton in Scottish sea-lochs. In Proceedings of a NATO advanced study workshop on the Role of Freshwater Outflow in Coastal Marine Ecosystems, eds. Skreslet, S. & Drinkwater, K., pp. 205218. Berlin: Springer-Verlag.CrossRefGoogle Scholar
Tett, P. & Wallis, A. 1978. The general cycle of chlorophyll standing crop in Loch Creran. Journal of Ecology 66, 227239.CrossRefGoogle Scholar
Tett, P., Drysdale, M. & Shaw, J. 1981. Phytoplankton in Loch Creran during 1979 and its effect on the rearing of oyster larvae. Oban: Scottish Marine Biological Association, Internal Report 52.Google Scholar
Tyler, I., Grantham, B., MacNaughton, E. & Tett, P. 1983. Salinity and temperature profiles on Loch Creran, 1978. Oban: Scottish Marine Biological Association, Internal Report 84.Google Scholar
Wood, B. J. B., Tett, P. B. & Edwards, A. 1973. An introduction to the phytoplankton, primary production and relevant hydrography of Loch Etive. Journal of Ecology 61, 569585.CrossRefGoogle Scholar