Abstract
The number of phytoplankton, zooplankton, and macrobenthos species was studied in continental lakes of diverse origin, geographical position, and hydrochemical (water mineralization) and morphological (area and capacity) characteristics. It is shown that the diversity of benthos communities depends on mineralization, area, and capacity of the waterbody, the dependence on area and mineralization being stronger than the dependence on capacity. Zooplankton community diversity depends on water mineralization and, to a very small extent, on waterbody area. The number of phytoplankton species in a lake is not strictly determined by morphometric characteristics and water mineralization. This number is to a greater extent dependent on other factors (e.g., light, nutrients, etc.). The largest number of benthos and plankton species was observed in waterbodies with water mineralization around 0.4 g/l. Increase in mineralization leads not only to decrease in species number, but also to simplification of community structure in plankton and bottom organisms, which is reflected by the Shannon index of diversity decreasing accordingly. The studied relations show wide dispersal in the number of species that can result, beside other factors unaccounted for, from the uneven reliability of the identifications and recordings of plankton and benthos species due to the different proficiency level of experts in taxonomy and systematics.
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References
Alimov, A.F., Vvedenie v produktsionnuyu gidrobiologiyu (Introduction in Production Hydrobiology), Leningrad: Gidrometeoizdat, 1989.
Alimov, A.F., Investigation of Biodiversity in Communities of Plankton, Benthos, and in Ecosystems of Freshwater Water Bodies of Different Productivity, Izv. RAN, Ser. Biol., 2001, no. 1, pp. 87–95.
Alimov, A.F., Morphometry of Lakes, Number of Species, and Biomass of Hydrobionts, Biol. Vnutrennikh vod, 2006, no. 1, pp. 3–7.
Balushkins, E.V., Golubkov, S.M., Golubkov, M.S., and Litvinchuk, L.F., Structural-Functional Characteristics of Ecosystenms of Small Saline Lakes of Cromea, Biol. Vnutrennikh vod, 2007, no. 2, pp. 11–19.
Biologicheskaya produktivnost’ Severnykh ozer (Biological Productivity of Northern Lakes), Leningrad: Nauka, Parts 1–2, 1975.
Ivanova, M.B., Dependence of Number of Species in Lake Zooplankton on General Water Mineralization and pH, Biol. Vnutrennikh vod, 2005, no. 1, pp. 64–68.
Ivanova, M.B. and Kazantseva, T.I., Effect of pH and Total Water Mineralization on Species Diversity of Pelagic Zooplankton in Lakes, Ekologiya, 2006, no. 4, pp. 294–300.
Ozera Khakassii i ikh rybokhozyaistvennoe Znachenie (Lakes of Khakassia and Their Significance for Fishery), Krasnoyarsk: Krasnoyarskoe knizhnoe izdatel’stvo, 1976.
Sodovye ozera Zabaikal’ya (ekologiya i produtivnost’) (Soda Lakes of Transbaikalia (Ecology and Productivity)), Novosibirsk, Nauka, 1991.
Unikal’nye ekosistemy solonovatovodnykh karstovykh ozer Srednego Povolzh’ya (Unique Ecosystems of Brackish Karst Lakes of the Middle Volga), Kazan: Kazan University, 2001.
Ekologicheskie sistemy Narochanskikh ozer (Ecological Systems of Naroch Lakes), Minsk: Minsk Univ., 1985.
Aladin, N.V. and Plotnikov, I.S., Large Saline Lakes of Former USSR: a Summary Review, Hydrobiologia, 1993, vol. 267, pp. 1–12.
Dejoux, C., Benthic Invertebrates of Some Saline Lakes of the Sud Lipez Region, Bolivia, Hydrobiologia, 1993, vol. 267, pp 257–267.
Gamito, S., Benthic Ecology of Semi-Natural Coastal Lagoons in the Rea Formose (Southern Portugal), Exposed to Different Water Renewal Regims, Hydrobiologia, 2006, vol. 55, pp. 75–87.
Golubkov, M.S., Golubkov, S.M., Gubelit, Y.I., et al., Primary Production and Composition of Phytoplankton Assemblages in Hypersaline Lakes of Crimea, Proc. Zool. Inst. Russ. Acad. Sci., 2006, vol. 310, pp. 59–66.
Green, J., Zooplankton Associations in East Africans Lakes, Spanning a Wide Salinity Region, Hydrobiologia, 1993, vol. 267, pp. 249–256.
Hammer, U.T., The Saline Lakes of Saskatchewan. 1. Background and Rational for Saline Lakes Research, Int. Rev. ges. Hydrobiol., 1978, vol. 63, pp. 173–177.
Hammer, U.T., Saline Lake Ecosystems of the World, Dordrecht; Boston; Lancaster: Dr. W. Junk, 1986.
Hammer, U.T., The Effect of Climate Change of the Salinity? Water Levels and Biota of Canadian Prairie Saline Lakes, Verh. Int. Ver. theor. und angew. Limnol., 1990, vol. 24, pp. 321–326.
Hammer, U.T., Shames, J., and Hynes, R.C. The Distribution and Abundance of Algal in Saline Lakes of Saskatchewan, Canada, Hydrobiologia, 1983, vol. 105, pp. 1–26.
Hammer, U.T., Sheard, J.S., and Kranabetter, J., Distribution and Abundance of Littoral Benthic Fauna in Canadian Prairie Saline Lakes, Hydrobiologia, 1990, vol. 197, pp. 173–192.
Pinder, A.M., Halse, S.A., McRae, J.M., and Shiel, R.J., Occurrence of Aquatic Invertebrates of the Wheatbelt Region of Western Australia in Relation to Salinity, Hydrobiologia, 2005, vol. 543, pp. 1–24.
Timms, B.V., Animal Communities in Three Victorian Lakes of Differing Salinity, Hydrobiologia, 1981, vol. 81, pp. 181–193.
Timms, B.V., A Study of Benthic Communities in Some Shallow Saline Lakes of Western Victoria, Australia, Hydrobiologia, 1983, vol. 105, pp. 165–177.
Timms, B.V., Saline Lakes of the Paroo, Inland New South Wales, Australia, Hydrobiologia, 1993, vol. 267, pp. 269–289.
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Original Russian Text © A.F. Alimov, 2008, published in Biologiya Vnutrennikh Vod, No. 1, 2008, pp. 3–8.
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Alimov, A.F. Relations between biological diversity in continental waterbodies and their morphometry and water mineralization. Inland Water Biol 1, 1–6 (2008). https://doi.org/10.1007/s12212-008-1001-6
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DOI: https://doi.org/10.1007/s12212-008-1001-6