%0 Journal Article %1 kot96 %A Kot, Mark %A Lewis, Mark A. %A van den Driessche, P. %D 1996 %I Ecological Society of America %J Ecology %K dispersal invasions long_distance_dispersal parallel_adaptation %N 7 %P 2027--2042 %T Dispersal Data and the Spread of Invading Organisms %U http://www.jstor.org/stable/2265698 %V 77 %X Models that describe the spread of invading organisms often assume that the dispersal distances of propagules are normally distributed. In contrast, measured dispersal curves are typically leptokurtic, not normal. In this paper, we consider a class of models, integrodifference equations, that directly incorporate detailed dispersal data as well as population growth dynamics. We provide explicit formulas for the speed of invasion for compensatory growth and for different choices of the propagule redistribution kernel and apply these formulas to the spread of D. pseudoobscura. We observe that: (1) the speed of invasion of a spreading population is extremely sensitive to the precise shape of the redistribution kernel and, in particular, to the tail of the distribution; (2) fat-tailed kernels can generate accelerating invasions rather than constant-speed travelling waves; (3) normal redistribution kernels (and by inference, many reaction-diffusion models) may grossly underestimate rates of spread of invading populations in comparison with models that incorporate more realistic leptokurtic distributions; and (4) the relative superiority of different redistribution kernels depends, in general, on the precise magnitude of the net reproductive rate. The addition of an Allee effect to an integrodifference equation may decrease the overall rate of spread. An Allee effect may also introduce a critical range; the population must surpass this spatial threshold in order to invade successfully. Fat-tailed kernels and Allee effects provide alternative explanations for the accelerating rates of spread observed for many invasions.

@article{kot96, abstract = {Models that describe the spread of invading organisms often assume that the dispersal distances of propagules are normally distributed. In contrast, measured dispersal curves are typically leptokurtic, not normal. In this paper, we consider a class of models, integrodifference equations, that directly incorporate detailed dispersal data as well as population growth dynamics. We provide explicit formulas for the speed of invasion for compensatory growth and for different choices of the propagule redistribution kernel and apply these formulas to the spread of D. pseudoobscura. We observe that: (1) the speed of invasion of a spreading population is extremely sensitive to the precise shape of the redistribution kernel and, in particular, to the tail of the distribution; (2) fat-tailed kernels can generate accelerating invasions rather than constant-speed travelling waves; (3) normal redistribution kernels (and by inference, many reaction-diffusion models) may grossly underestimate rates of spread of invading populations in comparison with models that incorporate more realistic leptokurtic distributions; and (4) the relative superiority of different redistribution kernels depends, in general, on the precise magnitude of the net reproductive rate. The addition of an Allee effect to an integrodifference equation may decrease the overall rate of spread. An Allee effect may also introduce a critical range; the population must surpass this spatial threshold in order to invade successfully. Fat-tailed kernels and Allee effects provide alternative explanations for the accelerating rates of spread observed for many invasions.}, added-at = {2009-12-02T23:02:27.000+0100}, author = {Kot, Mark and Lewis, Mark A. and van den Driessche, P.}, biburl = {https://www.bibsonomy.org/bibtex/2daf92d1d3f9dd6334d1ece2bba1ae71f/peter.ralph}, copyright = {Copyright © 1996 Ecological Society of America}, description = {Dispersal Data and the Spread of Invading Organisms}, interhash = {27c5e733753089d011a6139757619681}, intrahash = {daf92d1d3f9dd6334d1ece2bba1ae71f}, issn = {00129658}, journal = {Ecology}, jstor_articletype = {primary_article}, jstor_formatteddate = {Oct., 1996}, keywords = {dispersal invasions long_distance_dispersal parallel_adaptation}, number = 7, pages = {2027--2042}, publisher = {Ecological Society of America}, timestamp = {2011-04-27T22:03:56.000+0200}, title = {Dispersal Data and the Spread of Invading Organisms}, url = {http://www.jstor.org/stable/2265698}, volume = 77, year = 1996 }