Soil water storage appears to compensate for climatic aridity at the xeric margin of European tree species distribution |
| |
| Authors: | Karl H. Mellert Jonathan Lenoir Susanne Winter Christian Kölling Andraž Čarni Isabel Dorado-Liñán Jean-Claude Gégout Axel Göttlein Daniel Hornstein Matthias Jantsch Nina Juvan Eckart Kolb Eduardo López-Senespleda Annette Menzel Dejan Stojanović Steffen Täger Ioannis Tsiripidis Thomas Wohlgemuth Joerg Ewald |
| |
| Affiliation: | 1.Forest Nutrition and Water Resources,Technical University of Munich,Freising,Germany;2.UR “Ecologie et dynamique des systèmes anthropisés” (EDYSAN, FRE 3498 CNRS-UPJV),Université de Picardie Jules Verne,Amiens Cedex 1,France;3.WWF – World Wide Fund for Nature,Berlin,Germany;4.AELF Roth,Roth,Germany;5.Research Center of the Slovenian Academy of Sciences and Arts,Institute of Biology,Ljubljana,Slovenia;6.Univerza of Nova Gorica,Nova Gorica,Slovenia;7.Forest Research Centre,Instituto Nacional de Investigación y Tecnología Agraria y Alimentaria (INIA-CIFOR),Madrid,Spain;8.LERFoB,Agro Paris Tech, INRA,Nancy,France;9.Faculty of Forestry,University of Applied Sciences Weihenstephan Triesdorf,Freising,Germany;10.Bayerische Landesanstalt für Wald und Forstwirtschaft,Freising,Germany;11.Ecoclimatology,Technical University of Munich,Freising,Germany;12.Institute for Advanced Study,Garching,Germany;13.Institute of Lowland Forestry and Environment,University of Novi Sad,Novi Sad,Serbia;14.Faculty of Agriculture,University of Novi Sad,Novi Sad,Serbia;15.Department of Botany, School of Biology,Aristotle University of Thessaloniki,Thessaloniki,Greece;16.Swiss Federal Institute for Forest, Snow and Landscape Research WSL,Birmensdorf,Switzerland |
| |
| Abstract: | Based on macroecological data, we test the hypothesis whether European tree species of temperate and boreal distribution maintain their water and nutrient supply in the more arid southern margin of their distribution range by shifting to more fertile soils with higher water storage than in their humid core distribution range (cf. soil compensatory effects). To answer this question, we gathered a large dataset with more than 200,000 plots that we related to summer aridity (SA), derived from WorldClim data, as well as soil available water capacity (AWC) and soil nutrient status, derived from the European soil database. The soil compensatory effects on tree species distribution were tested through generalized additive models. The hypothesis of soil compensatory effects on tree species distribution under limiting aridity was supported in terms of statistical significance and plausibility. Compared to a bioclimatic baseline model, inclusion of soil variables systematically improved the models’ goodness of fit. However, the relevance measured as the gain in predictive performance was small, with largest improvements for P. sylvestris, Q. petraea and A. alba. All studied species, except P. sylvestris, preferred high AWC under high SA. For F. sylvatica, P. abies and Q. petraea, the compensatory effect of soil AWC under high SA was even more pronounced on acidic soils. Soil compensatory effects might have decisive implications for tree species redistribution and forest management strategies under anthropogenic climate change. Therefore, soil compensatory effects deserve more intensive investigation, ideally, in studies combining different spatial scales to reduce the uncertainty associated with the precision of soil information. |
| |
| Keywords: | |
| 本文献已被 SpringerLink 等数据库收录! |
|
