Abstract
The Maximum Entropy Theory of Ecology (METE) predicts a universal species–area relationship (SAR) that can be fully characterized using only the total abundance (N) and species richness (S) at a single spatial scale. This theory has shown promise for characterizing scale dependence in the SAR. However, there are currently four different approaches to applying METE to predict the SAR and it is unclear which approach should be used due to a lack of empirical comparison. Specifically, METE can be applied recursively or non-recursively and can use either a theoretical or observed species-abundance distribution (SAD). We compared the four different combinations of approaches using empirical data from 16 datasets containing over 1000 species and 300,000 individual trees and herbs. In general, METE accurately downscaled the SAR (R2 > 0.94), but the recursive approach consistently under-predicted richness. METE’s accuracy did not depend strongly on using the observed or predicted SAD. This suggests that the best approach to scaling diversity using METE is to use a combination of non-recursive scaling and the theoretical abundance distribution, which allows predictions to be made across a broad range of spatial scales with only knowledge of the species richness and total abundance at a single scale.
Highlights
The species–area relationship (SAR) is a fundamental ecological pattern that characterizes the change in species richness as a function of spatial scale
Downscaling richness The Maximum Entropy Theory of Ecology (METE) approach to predicting the SAR is a two-step application of the maximum entropy formalism (MaxEnt): (1) MaxEnt is first used to predict the species-abundance distribution (SAD) which represents the probability that a species has abundance n0 in a community of area A0 with S0 species and N0 individuals, (n0|N0,S0,A0), and (2) MaxEnt is used to predict the intra-specific, spatial-abundance distribution which represents the probability that n out of n0 individuals of a species are located in a random quadrat of area A drawn from a total area A0, (n|A,n0,A0)
The SAD was well characterized by the METE predictions (R2 = 0.95); METE did on average predict slightly more uneven communities
Summary
The species–area relationship (SAR) is a fundamental ecological pattern that characterizes the change in species richness as a function of spatial scale. Applications involving the SAR depend strongly on the form of the relationship (Guilhaumon et al, 2008) which is known to change with spatial scale (Palmer & White, 1994; McGlinn & Hurlbert, 2012). The Maximum Entropy Theory of Ecology (METE) is a unified theory that shows promise for characterizing a variety of macroecological patterns including the speciesabundance distribution, a suite of relationships between body-size and abundance, and a number of spatial patterns including the species–area relationship (Harte et al, 2008; How to cite this article McGlinn et al (2013), An empirical evaluation of four variants of a universal species–area relationship.
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