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The Rockall slope current and shelf-edge processes

Published online by Cambridge University Press:  05 December 2011

J. M. Huthnance
J. M. Huthnance
Affiliation:
Institute of Oceanographic Sciences, Bidston Observatory, Birkenhead L43 7RA, U.K.
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Synopsis

Recent knowledge of physical-oceanographic processes is reviewed for the eastern shelf-edge boundary of the Rockall Channel.

A year-round northward current flows along the steep continental slope. Mean currents vary from 3 to 30cm/s, generally increasing northwards, but estimates of transport inshore of the 2000 m depth contour are much more consistent, averaging about 1·5 × 106m3/s. The current is thought to be forced largely by a long-shelf pressure gradient, associated with large-scale N-S density variations in the upper ocean.

Although cross-slope changes of temperature and salinity are much less than occur, for example, east of the U.S.A., cross-slope exchange velocities appear to be only around 2cm/s (1/5 of long-slope fluctuations). There is a sharp change between winter-cooled water on the shelf and adjacent slope water. Upwelling against the upper continental slope may occur following northerly long-slope winds. Tidal currents and surges depend strongly on continental shelf wave properties. At near-diurnal frequencies, and in response to winds of short scale (< 100 km), clockwise-rotating currents near the shelf break are expected, especially where the shelf is broadest. Tidal currents show this character.

Internal tides are significant; any non-linearity is most likely when stratification is present but weak. Bottom stirring has been observed, and may be important at some depth (where the bottom slope becomes as steep as the semi-diurnal internal characteristics) almost everywhere around the Rockall Channel. The energetic internal waves should contribute significant internal mixing as they approach the shelf break, intensify and dissipate.

Type
Research Article
Information
Proceedings of the Royal Society of Edinburgh, Section B: Biological Sciences , Volume 88: The Oceanography of the Rockall Channel , 1986 , pp. 83 - 101
Copyright
Copyright © Royal Society of Edinburgh 1986

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References

Alcock, G. A. 1982. Offshore bottom pressure records. North Channel of the Irish Sea 1979. Malin Shelf 1979. Rockall Trough 1979. Institute of Oceanographic Sciences, Data Report 27 (unpublished manuscript).Google Scholar
Allen, J. S. 1980. Models of wind-driven currents on the continental shelf. Annual Reviews of Fluid Mechanics 12, 389–133.CrossRefGoogle Scholar
Baines, P. G. 1974. The generation of internal tides over steep continental slopes. Philosophical Transactions of the Royal Society of London 277A, 2758.Google Scholar
Booth, D. A. 1981. Oscillatory currents in the Rockall Trough. Scottish Marine Biological Association, Marine Physics Report 15.Google Scholar
Booth, D. A. 1985. Heat flux across the Scottish shelf edge. Ocean Modelling 64, 1415, unpublished manuscript.Google Scholar
Booth, D. A. & Ellett, D. J. 1983. The Scottish continental slope current. Continental Shelf Research 2, 127146.Google Scholar
Booth, D. A. & Ellett, D. J. & Meldrum, D. T. 1984. Drifting buoys in the northeast Atlantic and Norwegian Sea. ICES Hydrography Committee, CM. 1984/C:27.Google Scholar
Cartwright, D. E. 1969. Extraordinary tidal currents near St Kilda. Nature, London 233, 928932.CrossRefGoogle Scholar
Cartwright, D. E., Huthnance, J. M., Spencer, R. & Vassie, J. M. 1980. On the St Kilda shelf tidal regime. Deep-Sea Research 21 A, 6170.CrossRefGoogle Scholar
Collings, I. L. & Grimshaw, R. 1980. The effect of topography on the stability of a barotropic coastal current. Dynamics of Atmospheres and Oceans 5, 83106.CrossRefGoogle Scholar
Csanady, G. T. 1978. The arrested topographic wave. Journal of Physical Oceanography 8, 4762.Google Scholar
Csanady, G. T. 1984. The influence of wind stress and river runoff on a shelf-sea front. Journal of Physical Oceanography 14, 13831392.Google Scholar
Davies, A. M. & Heaps, N. S. 1980. Influence of the Norwegian Trench on the wind-driven circulation of the North Sea. Tellus 32, 164175.CrossRefGoogle Scholar
Dickson, R. R., Garbutt, P. A. & Pillai, V. N. 1980. Satellite evidence of enhanced upwelling along the European continental slope. Journal of Physical Oceanography 10, 813819.2.0.CO;2>CrossRefGoogle Scholar
Dickson, R. R., Garbutt, P. A. & Pillai, V. N. & McCave, I. N. 1986. Nepheloid layers on the continental slope west of Porcupine Bank. Deep-Sea Research 33, 791818.CrossRefGoogle Scholar
Dooley, H. D. 1984. Aspects of oceanographic variability on Scottish fishing grounds. Ph.D. Thesis, University of Aberdeen.Google Scholar
Dooley, H. D. & Meincke, J. 1981. Circulation and water masses in the Faroese Channels during Overflow '73. Deutsche Hydrographische Zeitschrift 34, 4155.CrossRefGoogle Scholar
Ellett, D. J. & Martin, J. H. A. 1973. The physical and chemical oceanography of the Rockall Channel. Deep-Sea Research 20, 585625.Google Scholar
Ellett, D. J. & Martin, J. H. A., Dooley, H. D. & Hill, H. W. 1979. Is there a North-east Atlantic slope current? ICES Hydrography Committee, CM. 1979/C:35.Google Scholar
Flather, R. A. 1981. Results from a model of the north east Atlantic relating to the Norwegian Coastal Current. Proceedings of a Symposium on the Norwegian Coastal Current, Geilo, Norway, 9–12 September 1980.Google Scholar
Gordon, R. L. & Huthnance, J. M. 1986. Storm driven continental shelf waves over the Scottish continental shelf. Continental Shelf Research, submitted.Google Scholar
Gould, W. J., Loynes, J. & Backhaus, J. 1985. Seasonality in slope current transports NW of Shetland. ICES Hydrography Committee, CM. 1985/C:7.Google Scholar
Heaps, N. S. 1980. A mechanism for local upwelling along the European continental slope. Oceanologica Acta 3, 449454.Google Scholar
Heathershaw, A. D. 1985. Some observations of internal wave current fluctuations at the shelf-edge and their implications for sediment transport. Continental Shelf Research 4, 485493.Google Scholar
Howarth, M. J. 1982. Non-tidal flow in the North Channel of the Irish Sea. In Hydrodynamics of semi-enclosed seas, ed. Nihoul, J. C. J., pp. 205241. Amsterdam: Elsevier.Google Scholar
Huthnance, J. M. 1973. The influence of topography on tidal currents. Ph.D. Thesis, University of Cambridge.Google Scholar
Huthnance, J. M. 1978. On coastal trapped waves; analysis and numerical calculation by inverse iteration. Journal of Physical Oceanography 8, 7492.Google Scholar
Huthnance, J. M. 1981. Waves and currents near the continental shelf edge. Progress in Oceanography 10, 193226.Google Scholar
Huthnance, J. M. 1983. Sub-tidal motion on the Scottish continental shelf, August-September 1971. Continental Shelf Research 1, 221236.Google Scholar
Huthnance, J. M. 1984. Slope currents and “JEBAR”. Journal of Physical Oceanography 14, 795810.2.0.CO;2>CrossRefGoogle Scholar
Huthnance, J. M. 1986a. The sub-tidal behaviour of the Celtic Sea. III: A model of shelf waves and surges on a wide shelf. Continental Shelf Research 5, 347377.Google Scholar
Huthnance, J. M. 1986b. Effects of longshore shelf variations on barotropic continental shelf waves, slope currents and ocean modes. Progress in Oceanography, submitted.Google Scholar
James, I. D. 1982. Tidal currents at two deep-sea moorings near the shelf edge. Deep-Sea Research 29A, 10991111.Google Scholar
Levine, M. D., Paulson, C. A., Briscoe, M. G., Weller, R. A. & Peters, H. 1983. Upper-ocean internal waves. Philosophical Transactions of the Royal Society of London 308A, 389405.Google Scholar
McCreary, J. P. 1981. A linear stratified ocean model of the coastal undercurrent. Philosophical Transactions of the Royal Society of London 302A, 385413.Google Scholar
Pingree, R. D. 1979. Baroclinic eddies bordering the Celtic Sea in late summer. Journal of the Marine Biological Association of the United Kingdom 59, 689698.Google Scholar
Pingree, R. D., Griffiths, D. K. & Mardell, G. T. 1983. The structure of the internal tide at the Celtic Sea shelf break. Journal of the Marine Biological Association of the United Kingdom 64, 99113.Google Scholar
Pingree, R. D. & Griffiths, D. K. 1984. Trapped diurnal waves on Porcupine and Rockall Banks. Journal of the Marine Biological Association of the United Kingdom 64, 889897.Google Scholar
Pingree, R. D. & Mardell, G. T. 1981. Slope turbulence, internal waves and phytoplankton growth at the Celtic Sea shelf-break. Philosophical Transactions of the Royal Society of London 302A, 663682.Google Scholar
Pingree, R. D. & Mardell, G.T. 1984. Solitary internal waves in the Celtic Sea. Progress in Oceanography 14, 431441.Google Scholar
Pugh, D. T. & Thompson, K. R. 1986. The sub-tidal behaviour of the Celtic Sea. I: Sea level and bottom pressures. Continental Shelf Research 5, 293319.Google Scholar
Simpson, J. H. & Hunter, J. R. 1974. Fronts in the Irish Sea. Nature, London 250, 404406.CrossRefGoogle Scholar
Smith, R. 1975. Second-order turning point problems in oceanography. Deep-Sea Research 22, 837852.Google Scholar
Stommel, H. 1948. The westward intensification of wind-driven ocean currents. Transactions of the American Geophysical Union 29, 202206.Google Scholar
Sturges, W. 1974. Sea level slope along continental boundaries. Journal of Geophysical Research 79, 825830.Google Scholar
Swallow, J. C., Gould, W. J. & Saunders, P. M. 1977. Evidence for a poleward eastern boundary current in the North Atlantic ocean. ICES Hydrography Committee, CM. 1977/C:32.Google Scholar
Voorhis, A. D., Webb, D. C. & Millard, R. C. 1976. Current structure and mixing in the shelf/slope water front south of New England. Journal of Geophysical Research 81, 36953708.CrossRefGoogle Scholar