Tree diversity and the temporal stability of mountain forest productivity: testing the effect of species composition, through asynchrony and overyielding

Climate change modifies ecosystem processes directly through its effect on environmental conditions, but also indirectly by changing community composition. Theoretical studies and grassland experiments suggest that diversity may increase and stabilize communities’ productivity over time. Few recent...

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Bibliographic Details
Published in:European journal of forest research 2021-04, Vol.140 (2), p.273-286
Main Authors: Jourdan, Marion, Piedallu, Christian, Baudry, Jonas, Defossez, Emmanuel, Morin, Xavier
Format: Article
Language:English
Subjects:
Beech
Biomedical and Life Sciences
Climate change
Climatic conditions
Community composition
Composition effects
Ecological effects
Ecological function
Ecosystem assessment
Ecosystems
Environmental conditions
Environmental effects
Forest ecosystems
Forest management
Forest productivity
Forestry
Forests
Grasslands
Life Sciences
Monoculture
Mountain forests
Mountains
Original Paper
Plant diversity
Plant Ecology
Plant Sciences
Productivity
Species composition
Stability
Timber
Tree rings
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Summary:Climate change modifies ecosystem processes directly through its effect on environmental conditions, but also indirectly by changing community composition. Theoretical studies and grassland experiments suggest that diversity may increase and stabilize communities’ productivity over time. Few recent studies on forest ecosystems suggested the same pattern but with a larger variability between the results. In this paper, we aimed to test stabilizing diversity effect for two kinds of mixtures ( Fagus sylvatica – Quercus pubescens and F. sylvatica – Abies alba ), and to assess how climate may affect the patterns. We used tree ring data from forest plots triplets distributed along a latitudinal gradient across French Alps, adapting NBE approach to study temporal stability. We found that diversity effect on stability in productivity varies with stand composition. Most beech-fir stands showed a greater stability in productivity over time than monocultures, while beech-oak stands showed a less stable productivity. Considering nonadditive effects, no significant trends were found, regardless of the type of mixed stands considered. We further highlighted that these patterns could be partially explained by asynchrony between species responses (notably to variation in temperature or precipitation), overyielding and climatic conditions. We also showed that the intensity of the diversity effect on stability varies along the ecological gradient, consistently with the stress gradient hypothesis for beech in beech-oak forests, but not for beech-fir forests. This study showed the importance of the species identity on the relationships between diversity, climate and stability of forest productivity. Better depicting diversity and composition effects on forest ecosystem functioning appears to be crucial for forest managers to promote forest adaptation and maintain timber resource in the context of ongoing climate change.
ISSN:1612-4669
1612-4677
DOI:10.1007/s10342-020-01329-w