4.5 Article

Soil factors improve predictions of plant species distribution in a mountain environment

Journal

Publisher

SAGE PUBLICATIONS LTD
DOI: 10.1177/0309133317738162

Keywords

Soil pH; very high resolution; mountain flora; Swiss Alps; species distribution models; carbon isotope composition; soil organic matter

Funding

  1. Swiss National Science Foundation [31003A-1528661, CR23I2_162754]
  2. Swiss National Science Foundation (SNF) [CR23I2_162754] Funding Source: Swiss National Science Foundation (SNF)

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Explanatory studies suggest that using very high resolution (VHR, 1-5 m resolution) topo-climatic predictors may improve the predictive power of plant species distribution models (SDMs). However, the use of VHR topo-climatic data alone was recently shown not to significantly improve SDM predictions. This suggests that new ecologically-meaningful VHR variables based on more direct field measurements are needed, especially since non topo-climatic variables, such as soil parameters, are important for plants. In this study, we investigated the effects of adding mapped VHR predictors at a 5 m resolution, including field measurements of temperature, carbon isotope composition of soil organic matter (C-13(SOM) values) and soil pH, to topo-climatic predictors in SDMs for the Swiss Alps. We used data from field temperature loggers to construct temperature maps, and we modelled the geographic variation in C-13(SOM) and soil pH values. We then tested the effect of adding these VHR mapped variables as predictors into 154 plant SDMs and assessed the improvement in spatial predictions across the study area. Our results demonstrate that the use of VHR predictors based on more proximal field measurements, particularly soil parameters, can significantly increase the predictive power of models. Predicted soil pH was the second most important predictor after temperature, and predicted C-13(SOM) was fourth. The greatest increase in model performance was for species found at high elevation (i.e. 1500-2000 m a.s.l.). Addition of predicted soil factors thus allowed better capturing of plant requirements in our models, showing that these can explain species distributions in ways complementary to topo-climatic variables. Modelling techniques to generalize edaphic information in space and then predict plant species distributions revealed a great potential in complex landscapes such as the mountain region considered in this study.

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