RT Journal Article
SR Electronic
T1 Coherence of Terrestrial Vertebrate Species Richness with External Drivers Across Scales and Taxonomic Groups
JF bioRxiv
FD Cold Spring Harbor Laboratory
SP 2022.01.21.477239
DO 10.1101/2022.01.21.477239
A1 Conor P. B. O’Malley
A1 Gareth G. Roberts
A1 Philip D. Mannion
A1 Jan Hackel
A1 Yanghua Wang
YR 2022
UL http://biorxiv.org/content/early/2022/09/06/2022.01.21.477239.abstract
AB Aim Understanding connections between environment and biodiversity is crucial for conservation, identifying causes of ecosystem stress, and predicting population responses to changing environments. Explaining biodiversity requires an understanding of how species richness and environment co-vary across scales. Here, we identify scales and locations at which biodiversity is generated and correlates with environment.Location Full latitudinal range per continent.Time period Present-day.Major taxa studied Terrestrial vertebrates: all mammals, carnivorans, bats, songbirds, humming-birds, amphibians.Methods We describe the use of wavelet power spectra, cross-power and coherence for identifying scale-dependent trends across Earth’s surface. Spectra reveal scale- and location-dependent coherence between species richness and topography (E), mean annual precipitation (Pn), temperature (Tm) and annual temperature range (ΔT).Results > 97% of species richness of taxa studied is generated at large scales, i.e. wavelengths ≳ 103 km, with 30–69% generated at scales ≳ 104 km. At these scales, richness tends to be highly coherent and anti-correlated with E and ΔT, and positively correlated with Pn and Tm. Coherence between carnivoran richness and ΔT is low across scales, implying insensitivity to seasonal temperature variations. Conversely, amphibian richness is strongly anti-correlated with ΔT at large scales. At scales ≲ 103 km, examined taxa, except carnivorans, show highest richness within the tropics. Terrestrial plateaux exhibit high coherence between carnivorans and E at scales ~ 103 km, consistent with contribution of large-scale tectonic processes to biodiversity. Results are similar across different continents and for global latitudinal averages. Spectral admittance permits derivation of rules-of-thumb relating long-wavelength environmental and species richness trends.Main conclusions Sensitivities of mammal, bird and amphibian populations to environment are highly scale-dependent. At large scales, carnivoran richness is largely independent of temperature and precipitation, whereas amphibian richness correlates strongly with precipitation and temperature, and anti-correlated with temperature range. These results pave the way for spectral-based calibration of models that predict biodiversity response to climate change scenarios.Competing Interest StatementThe authors have declared no competing interest.