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Synthesis and future research directions linking tree diversity to growth, survival, and damage in a global network of tree diversity experiments
Auteur(s)
Jake J. Grossman
Margot Vanhellemont
Nadia Barsoum
Jürgen Bauhus
Helge Bruelheide
Bastien Castagneyrol
Jeannine Cavender-Bares
Nico Eisenhauer
Olga Ferlian
Dominique Gravel
Andy Hector
Hervé Jactel
Holger Kreft
Simone Mereu
Christian Messier
Bart Muys
Charles Nock
Alain Paquette
John Parker
Michael P. Perring
Quentin Ponette
Peter B. Reich
Andreas Schuldt
Michael Staab
Martin Weih
Michael Scherer-Lorenzen
Kris Verheyen
Date de parution
2018
In
Environmental and Experimental Botany
Vol.
152
De la page
68
A la page
89
Résumé
Despite considerable research demonstrating that biodiversity increases productivity in forests and regulates herbivory and pathogen damage, there remain gaps in our understanding of the shape, magnitude, and generality of these biodiversity-ecosystem functioning (BEF) relationships. Here, we review findings from TreeDivNet, a global network of 25 tree diversity experiments, on relationships between levels of biodiversity and (a) tree growth and survival and (b) damage to trees from pests and pathogens. Tree diversity often improved the survival and above- and belowground growth of young trees. The mechanistic bases of the diversity effects on tree growth and survival include both selection effects (i.e., an increasing impact of particular species in more species-rich communities) and complementary effects (e.g. related to resource differentiation and facilitation). Plant traits and abiotic stressors may mediate these relationships. Studies of the responses of invertebrate and vertebrate herbivory and pathogen damage have demonstrated that trees in more diverse experimental plots may experience more, less, or similar damage compared to conspecific trees in less diverse plots. Documented mechanisms producing these patterns include changes in concentration, frequency, and apparency of hosts; herbivore and pathogen diet breadth; the spatial scale of interactions; and herbivore and pathogen regulation by natural enemies. Our review of findings from TreeDivNet indicates that tree diversity experiments are extending BEF research across systems and scales, complementing previous BEF work in grasslands by providing opportunities to use remote sensing and spectral approaches to study BEF dynamics, integrate belowground and aboveground approaches, and trace the consequences of tree physiology for ecosystem functioning. This extension of BEF research into tree-dominated systems is improving ecologists’ capacity to understand the mechanistic bases behind BEF relationships. Tree diversity experiments also present opportunities for novel research. Since experimental tree diversity plantations enable measurements at tree, neighbourhood and plot level, they allow for explicit consideration of temporal and spatial scales in BEF dynamics. Presently, most TreeDivNet experiments have run for less than ten years. Given the longevity of trees, exciting results on BEF relationships are expected in the future.
Identifiants
Type de publication
journal article
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