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Species distribution modelling: Does one size fit all? A phytogeographic analysis of Salix in Ontario

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  • Stankowski, Philippe A.
  • Parker, William H.

Abstract

Empirical models for predicting the distribution of organisms from environmental data have often focused on principles of ecological niche theory. However, even at large scales, there is little agreement over how to represent the dimensions of a species’ niche. The performance of such models is greatly affected by the nature of species distributional and environmental data. Regional scale distribution models were developed for 30 willow species in Ontario to examine (i) the predictive ability of logistic regression analysis, and (ii) the effects of using different distributional and environmental data sets. Two original measures of model accuracy and over-prediction were employed and evaluated using independent data. Models based on unique combinations of monthly climate data predicted distributions most accurately for all species. Models based on a fixed set of variables, while generating the highest average probabilities of occurrence for certain species with limited ranges, resulted in the greatest under- and over-estimates of willow distributions. Comparisons of models demonstrated climatic patterns among willows of differing habit and habitat. The distribution of dwarf willow species, present only in the Ontario arctic, followed gradients of summer maximum temperatures. The distribution of the tree species in the southerly portions of the province followed gradients of fall and winter minimum temperatures. Regardless of distributional and environmental data input, no algorithm maximized model performance for all species. Individual species models require individual approaches; i.e., the variable selection technique, the set of environmental factors used as predictors, and the nature of species distributional data must be carefully matched to the intended application. An understanding of evolutionary processes enhances the meaningful interpretation of individual species models. Unless sampling bias and species prevalence can be accounted for, models based on collection point data are best used to guide field surveys. While inferred range data may be better suited to determine potential ecological niches, overestimation of species prevalence and environmental tolerance must be recognized. A combination of available distributional data types is recommended to best determine species niches, an important step in developing conservation strategies.

Suggested Citation

  • Stankowski, Philippe A. & Parker, William H., 2010. "Species distribution modelling: Does one size fit all? A phytogeographic analysis of Salix in Ontario," Ecological Modelling, Elsevier, vol. 221(13), pages 1655-1664.
    • Handle: RePEc:eee:ecomod:v:221:y:2010:i:13:p:1655-1664
    DOI: 10.1016/j.ecolmodel.2010.03.016
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    2. ,, 1999. "Problems And Solutions," Econometric Theory, Cambridge University Press, vol. 15(1), pages 151-160, February.
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    1. Stankowski, Philippe A. & Parker, William H., 2011. "Future distribution modelling: A stitch in time is not enough," Ecological Modelling, Elsevier, vol. 222(3), pages 567-572.
    2. Watling, James I. & Romañach, Stephanie S. & Bucklin, David N. & Speroterra, Carolina & Brandt, Laura A. & Pearlstine, Leonard G. & Mazzotti, Frank J., 2012. "Do bioclimate variables improve performance of climate envelope models?," Ecological Modelling, Elsevier, vol. 246(C), pages 79-85.

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