@article{01JBVVAQDCMB4TK7VB9JHZ9CKY,
  abstract     = {{Increasing tree diversity is considered a key management option to adapt forests to climate change. However, the effect of species diversity on a forest's ability to cope with extreme drought remains elusive. In this study, we assessed drought tolerance (xylem vulnerability to cavitation) and water stress (water potential), and combined them into a metric of drought-mortality risk (hydraulic safety margin) during extreme 2021 or 2022 summer droughts in five European tree diversity experiments encompassing different biomes. Overall, we found that drought-mortality risk was primarily driven by species identity (56.7% of the total variability), while tree diversity had a much lower effect (8% of the total variability). This result remained valid at the local scale (i.e within experiment) and across the studied European biomes. Tree diversity effect on drought-mortality risk was mediated by changes in water stress intensity, not by changes in xylem vulnerability to cavitation. Significant diversity effects were observed in all experiments, but those effects often varied from positive to negative across mixtures for a given species. Indeed, we found that the composition of the mixtures (i.e., the identities of the species mixed), but not the species richness of the mixture per se, is a driver of tree drought-mortality risk. This calls for a better understanding of the underlying mechanisms before tree diversity can be considered an operational adaption tool to extreme drought. Forest diversification should be considered jointly with management strategies focussed on favouring drought-tolerant species. Written Summary: Working with more than 20 species and 5 experimental forests in different European biomes, we show that the risk of a tree dying under extreme drought is mainly determined by its species identity, rather than whether it grows in a monoculture or a mixture. However, even if the effects of species richness are weak on average, certain species mixtures can drastically limit the risk of tree mortality under drought in certain species combinations. Understanding these mechanisms is essential for developing predictive and operational tools for management strategies to adapt forests to extreme drought.image}},
  articleno    = {{e17503}},
  author       = {{Decarsin, Renaud and Guillemot, Joannès and le Maire, Guerric and Blondeel, Haben and Meredieu, Céline and Achard, Emma and Bonal, Damien and Cochard, Hervé and Corso, Déborah and Delzon, Sylvain and Doucet, Zoé and Druel, Arsène and Grossiord, Charlotte and Torres‐Ruiz, José Manuel and Bauhus, Jürgen and Godbold, Douglas L. and Hajek, Peter and Jactel, Hervé and Jensen, Joel and Mereu, Simone and Ponette, Quentin and Rewald, Boris and Ruffault, Julien and Sandén, Hans and Scherer‐Lorenzen, Michael and Serrano‐León, Hernán and Simioni, Guillaume and Verheyen, Kris and Werner, Ramona and Martin‐StPaul, Nicolas}},
  issn         = {{1354-1013}},
  journal      = {{GLOBAL CHANGE BIOLOGY}},
  keywords     = {{forest adaptation,forest management,hydraulic traits,species interactions,species richness,tree diversity,water stress,xylem embolism,FAGUS-SYLVATICA L.,XYLEM VULNERABILITY,PLANT HYDRAULICS,EUROPEAN BEECH,CAVITATION,PLASTICITY,FORESTS,WATER}},
  language     = {{eng}},
  number       = {{9}},
  pages        = {{15}},
  title        = {{Tree drought–mortality risk depends more on intrinsic species resistance than on stand species diversity}},
  url          = {{http://doi.org/10.1111/gcb.17503}},
  volume       = {{30}},
  year         = {{2024}},
}

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