Abstract
A three-dimensional general circulation model has been developed to investigate mixing processes in Lake Baikal, Siberia. Emphasis is placed on the 4–5-month period when the lake is completely ice-covered, a time of particular importance to the re-population of the lake by diatoms. The model represents the top 250 m and includes a new mixing scheme developed specifically for the investigation of under-ice flows. The effects of spatial patterns of snow and ice transparency on circulation and temperature are investigated. In general, temperature profiles provide an indication of the extent and depth of mixing and are highly sensitive to the presence of snow and to the transparency of ice. Generated profiles agree well with in situ measurements, which are difficult to obtain during this period. The model is shown to be particularly successful in simulating mixing processes in Lake Baikal. The surface heat fluxes that are required for a model of this type were estimated using satellite data, which provide complete coverage of the lake within one image. An increase in albedo values of 20% has no significant impact on the development of the temperature profile. Finally, density driven currents generated in the model were investigated. The magnitudes of the model currents compared to observations suggest that the background flow under ice in the lake may be density driven.
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References
Botte, V. & A. Kay, 2000. A numerical study of plankton population dynamics in a deep lake during the passage of the Spring thermal bar. J. Marine Sys, 26: 367–386.
Cox, M. D., 1984. A primitive equation, 3-dimensional model of the ocean. Princeton Univ. GFDL Ocean Group Tech. Rep. 1.
Eppley, R. W., R. W. Holmes & J. D. Strickland, 1967. Sinking rates of marine phytoplankton measured with a fluorometer. J. Exp. Mar. Biol. Ecol. 1: 191.
Hohmann, R., R. Kipfer, F. Peeters, G. Piepke, D. M. Imboden & M. N. Shimaraev, 1997. Processes of deep-water renewal in Lake Baikal. Limnol. & Oceanogr, 42(5): 841–855.
Kelley D. E., 1997. Convection in ice-covered lakes: effects on algal suspension. J. Plankton Res. 1(12): 1859–1880.
Killworth, P., E. Carmack, R. Weiss, & R. Matear, 1996. Deep water renewal in Lake Baikal: Observations and Model. Limnol. & Oceanogr. 41: 1521–1538.
Kozhov, M., 1963. Lake Baikal and its Life. Dr W. Junk Publishers, The Hague.
Lawrence, S. P., M. R. Allen, D. L. T. Anderson & D. T. Llewellyn–Jones, 1998: Effects of subsurface ocean dynamics on instability waves in the tropical Pacific, J. Geophys. Res. 103: 18649–18663.
McCreary, J. P. & D. L. T. Anderson, 1991. An overview of coupled atmosphere models of El Nino and the Southern Oscillation. J. Geophys. Res. 96: 3125–3150.
Matthews, P. C. & S. I. Heaney, 1987. Solar heating and its influence on mixing in ice-covered lakes. Freshwater Biol. 18: 135–149.
Morassuti, M. P., 1989. Surface albedo parameterization in sea-ice models. Prog. Phys. Geog. 13: 348–366.
Pacanowski, R. C. & S. G. H. Philander, 1981. Parameterization of vertical mixing in numerical models of tropical oceans. J. Phys. Oceanogr. 11: 1443–1451.
Peeters, F., G. Piepke, R. Kipfer, R. Hohmann & D. M. Imboden, 1996. Description of stability and neutrally buoyant transport in freshwater lakes. Limnol. & Oceanogr 42 (8): 1711–1724.
Ravens, T. M., O. Kocsis, A. Wüest & N. Granin, 2000. Smallscale turbulence and vertical mixing in Lake Baikal. Limnol. & Oceanogr. 45(1): 159–173.
Shimaraev, M. N., N. Granin & A. A. Zhdanov, 1993. Deep ventilation of Lake Baikal waters due to spring thermal bars. Limnol. & Oceanogr. 38: 1068–1072.
Shimaraev, M. N., V. I. Verbolov, N. G. Granin & P. P. Sherstyankin, 1994. Physical Limnology of Lake Baikal: A review. Bicer print No. 2. M. N. Shimaraev & S. Okuda (eds).
Shine, K. P. & A. Henderson-Sellers, 1985. The sensitivity of a thermodynamic sea-ice model to changes in surface albedo parameterization. J. Geophys. Res. 90: 2243–2250.
Tsvetova, E. A., 1999. Mathematical modelling of Lake Baikal hydrodynamics. Hydrobiologia 47: 37–43.
Webster, I. T., 1995, Effect of wind on the distribution of phytoplankton cells in lakes. Limnol. & Oceanogr: 35: 989–1001.
Weiss, R. F., E. C. Carmack & V. M. Koropalov, 1991. Deep-water renewal and biological production in Lake Baikal. Nature 349: 665–669.
Zhdanov, A. A., N. G. Granin & M. N. Shimaraev, 2001. The generation mechanism of under-ice currents in Lake Baikal. Dokl. Earth Sci. 377A(3): 329–332.
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Lawrence, S.P., Hogeboom, K. & Core, H.L.L. A three-dimensional general circulation model of the surface layers of Lake Baikal. Hydrobiologia 487, 95–110 (2002). https://doi.org/10.1023/A:1022938009360
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DOI: https://doi.org/10.1023/A:1022938009360