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Abstract
This study tests the hypothesis that high species richness in small-bodied mammals results from higher speciation rates than in clades composed of large-bodied individuals. A right-skewed pattern is evident in size distributions of all mammal groups tested. Gaps between 100 g bins expand smoothly for the global mammal database. Less diverse mammal clades composed of large-sized individuals originated at relatively large size. Mechanisms promoting isolation and higher speciation rates in small mammals include the environmental mosaic, low absolute energy needs, small home range size, stenotopy, and intraspecific competition. A decline in diversity for the smallest size category in some clades suggests there is a lower limit in homoiotherms of about 1.5–2 g, possibly related to high metabolic rate and high surface area to volume ratio. Mammal size diversity from young Canadian ecosystems (≤19,000 years BP) is right-skewed, and diversity of species per unit area is approximately the same as for North America. Diversity and size distributions for mammals and select animal groups from southern Minnesota follow expected right-skewed patterns, suggesting the inverse relationship of body size and speciation rate is universal for complex metazoans. A logistic model is presented integrating γ and α diversity over evolutionary timescales.
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Acknowledgments
My interest in body size and its relationship to ecological and evolutionary processes derives directly from the influence of B. McNab, University of Florida. Mass and energy have been the dominant themes of his teaching and research. I thank John Damuth and an anonymous reviewer for comments on the manuscript.