Abstract
After the disappointing experiences with complex ecological models in the days of the International Biological Program, dynamic modelling has never really recovered a convincing niche in applied ecology. Simple generic models have become the tool par excellence for the development of theory. However, the popularity of these abstract theoretical models among practical ecologists is marginal. It is argued that the antagonism against such models is largely due to a misconception about their possible role in the process of unravelling the functioning of ecological communities. We discuss the pitfalls of analyzing the driving causal relationships in real world ecosystems, and evaluate role for minimal models in this context.
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References
Bloomfield, J. A., R. A. Park, D. Scavia & C. S. Zahorcak, 1974. Aquatic modelling in the eastern deciduous forest biome, U.S. International Biological Program. In E. Middlebrooks, D. H. Falkenberg & T. E. Maloney (eds), Modelling the Ecosystem Process. Ann Arbor, MI: Ann Arbor Science: 139–158.
Chamberlin, T. C., 1897. The method of multiple working hypotheses. J. Geol. 5: 837–848.
Conley, W., 1990. An ‘institute for theoretical ecology’–part I: what is ‘theoretical ecology’ and why do we need it? Coenoses 5: 177–179.
Connor, E. F. & D. S. Simberlof, 1979. The assembly of species communities: chance or competition? Ecology, 60: 1132–1140.
Edwards, P., 1972. The encyclopedia of philosophy. Collier Macmillan Publishers, London. 1: 56–66.
Elner, R. W. & R. L. Vadas, 1990. Inference in ecology: the sea urchin phenomenon in the northwestern atlantic. Am. Nat. 136: 108–125.
Levin, S. A., 1981. The role of theoretical population ecology in the description and understanding of populations in heterogeneous environments. Am. Zool. 21: 865–875.
Levins, R., 1968. Evolution in changing environments. Princeton University Press, Princeton, NJ.
Meijer, M.-L., E. H. R. Lammens, E. H. van Nes, A. W. Breukelaar, P. Hollebeek, R. B. Doef & H. Coops, 1993. The consequences of a reduction fishery on the trophic levels in lake Wolderwijd. Proceedings XXV SIL international congress. Verh. int. Limnol. Ver. (in press).
May, R. M., 1981. Theoretical ecology, principles and applications. Blackwell Scientific Publications, Oxford.
Montgomory, D. C. & E. A. Peck, 1982. Introduction to Linear Regression Analysis. Wiley, New York, 504 pp.
Nisbeth, R. M. & W. S. C. Gurney, 1982. Modelling Fluctuating Populations. Wiley, Chicester.
Platt, J. R., 1964. Strong Inference. Science 146: 347–353.
Qin, J. & S. T. Threlkeld, 1990. Experimental comparison of the effects of benthivorous fish and planktivorous fish on plankton community structure. Arch. Hydrobiol. 119: 121–141.
Quinn, J. F. & A. E. Dunham, 1983. On hypothesis testing in ecology and evolution. Am. Nat. 122: 602–617.
Rigler, F. H., 1982. Recognition of the possible: An advantage of empiricism in ecology. Can. J. Fish. aquat. Sci, 39: 1323–1331.
Roughgarden, J., 1983. Competition and theory in community ecology. Am. Nat. 122: 583–601.
Scheffer, M., 1989. Alternative stable states in eutrophic shallow freshwater ecosystems, a minimal model. Hydrobiol. Bull. 23: 73–83.
Scheffer, M., 1990. Multiplicity of stable states in freshwater systems. Hydrobiologia 200–201/Dev. Hydrobiol. 61: 475–487.
Scheffer, M., 1992. Fish and nutrients determines algal biomass: a minimal models. Oikos 62: 271–282.
Scheffer, M., M. R. de Redelijkheid & F. Noppert, 1992. Distribution and dynamics of submerged vegetation in a chain of shallow eutrophic lakes. Aquat. Bot. 42: 199–216.
Shapiro, J. & D. I. Wright, 1984. Lake restoration by biomanipulation: Round Lake, Minnesota, the first two years. Freshwat. Biol. 14: 371–388.
Simberlof, D., 1983. Competition theory, hypothesis testing, and other community-ecological buzzwords. Am. Nat. 122: 626–635.
Simons, T. J. & D. C. Lam, 1980. Some limitations of water quality models for large lakes: a case study of Lake Ontario. Wat. Resour. Res. 16: 105–116.
Strong, D. R., 1983. Natural variability and the manifold mechanisms of ecological communities. Am. Nat. 122: 636–660.
Threlkeld, S. T., 1994. Benthic—pelagic coupling in shallow water columns: an experimentalist’s perspective. Hydrobiologia 275–276/Dev. Hydrobiol. 94: 293–300.
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© 1994 Springer Science+Business Media Dordrecht
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Scheffer, M., Beets, J. (1994). Ecological models and the pitfalls of causality. In: Mortensen, E., Jeppesen, E., Søndergaard, M., Nielsen, L.K. (eds) Nutrient Dynamics and Biological Structure in Shallow Freshwater and Brackish Lakes. Developments in Hydrobiology, vol 94. Springer, Dordrecht. https://doi.org/10.1007/978-94-017-2460-9_10
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DOI: https://doi.org/10.1007/978-94-017-2460-9_10
Publisher Name: Springer, Dordrecht
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