Abstract
AbstractAimIt is widely accepted that biodiversity is influenced by both niche‐related and spatial processes from local to global scales. Their relative importance, however, is still disputed, and empirical tests are surprisingly scarce at the global scale. Here, we compare the importance of area (as a proxy for pure spatial processes) and environmental heterogeneity (as a proxy for niche‐related processes) for predicting native mammal species richness world‐wide and within biogeographical regions.LocationGlobal.Time periodWe analyse a spatial snapshot of richness data collated by the International Union for Conservation of Nature.Major taxa studiedAll terrestrial mammal species, including possibly extinct species and species with uncertain presence.MethodsWe applied a spreading dye algorithm to analyse how native mammal species richness changes with area and environmental heterogeneity. As measures for environmental heterogeneity, we used elevation ranges and precipitation ranges, which are well‐known correlates of species richness.ResultsWe found that environmental heterogeneity explained species richness relationships better than did area, suggesting that niche‐related processes are more prevalent than pure area effects at broad scales.Main conclusionsOur results imply that niche‐related processes are essential to understand broad‐scale species–area relationships and that habitat diversity is more important than area alone for the protection of global biodiversity.
Highlights
Understanding biodiversity patterns is a core interest in ecology
We found that environmental heterogeneity explained species richness relationships better than did area, suggesting that niche-related processes are more prevalent than pure area effects at broad scales
Main conclusions: Our results imply that niche-related processes are essential to understand broad-scale species–area relationships and that habitat diversity is more important than area alone for the protection of global biodiversity
Summary
Understanding biodiversity patterns is a core interest in ecology. One of the most pervasive of these patterns is the observation that the number of species contained in a spatial region increases with the area of that region. Given that heterogeneous environments offer more niches, coexistence and species richness should increase with environmental heterogeneity (Ben-Hur & Kadmon, 2020; Potts et al, 2004; Whittaker, 1998). This mechanism, known as the environmental heterogeneity hypothesis (Palmer, 2007), is supported by several studies reporting that environmental heterogeneity is an important predictor of species richness for various taxonomic groups (Burnett et al, 1998; Kerr & Packer, 1997) and across spatial scales (Stein et al, 2014). Given that environmental heterogeneity typically increases with area, it offers one possible explanation for observed species–area relationships
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