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Modelling native and alien vascular plant species richness: At which scales is geodiversity most relevant?
Author(s) -
Bailey Joseph J.,
Boyd Doreen S.,
Hjort Jan,
Lavers Chris P.,
Field Richard
Publication year - 2017
Publication title -
global ecology and biogeography
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 3.164
H-Index - 152
eISSN - 1466-8238
pISSN - 1466-822X
DOI - 10.1111/geb.12574
Subject(s) - geodiversity , species richness , landform , vascular plant , ecology , geography , physical geography , biodiversity , environmental science , biology , cartography
Abstract Aim To explore the scale dependence of relationships between novel measures of geodiversity and species richness of both native and alien vascular plants. Location Great Britain. Time period Data collected 1995–2015. Major taxa Vascular plants. Methods We calculated the species richness of terrestrial native and alien vascular plants (6,932 species in total) across the island of Great Britain at grain sizes of 1 km 2 ( n  = 219,964) and 100 km 2 ( n  = 2,121) and regional extents of 25–250 km diameter, centred around each 100‐km 2 cell. We compiled geodiversity data on landforms, soils, hydrological and geological features using existing national datasets, and used a newly developed geomorphometric method to extract landform coverage data (e.g., hollows, ridges, valleys, peaks). We used these as predictors of species richness alongside climate, commonly used topographic metrics, land‐cover variety and human population. We analysed species richness across scales using boosted regression tree (BRT) modelling and compared models with and without geodiversity data. Results Geodiversity significantly improved models over and above the widely used topographic metrics, particularly at smaller extents and the finer grain size, and slightly more so for native species richness. For each increase in extent, the contribution of climatic variables increased and that of geodiversity decreased. Of the geodiversity variables, automatically extracted landform data added the most explanatory power, but hydrology (rivers, lakes) and materials (soil, superficial deposits, geology) were also important. Main conclusions Geodiversity improves our understanding of, and our ability to model, the relationship between species richness and abiotic heterogeneity at multiple spatial scales by allowing us to get closer to the real‐world physical processes that affect patterns of life. The greatest benefit comes from measuring the constituent parts of geodiversity separately rather than one combined variable (as in most of the few studies to date). Automatically extracted landform data, the use of which is novel in ecology and biogeography, proved particularly valuable in our study.

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