Younger trees in the upper canopy are more sensitive but also more resilient to drought

Au, Tsun Fung; Maxwell, Justin T.; Robeson, Scott M.; Li, Jinbao; Siani, Sacha M. O.; Novick, Kimberly A.; Dannenberg, Matthew P.; Phillips, Richard P.; Li, Teng; Chen, Zhenju; Lenoir, Jonathan

Younger trees in the upper canopy are more sensitive but also more resilient to drought

Tsun Fung Au (), Justin T. Maxwell, Scott M. Robeson, Jinbao Li, Sacha M. O. Siani, Kimberly A. Novick, Matthew P. Dannenberg, Richard P. Phillips, Teng Li, Zhenju Chen and Jonathan Lenoir
Additional contact information
Tsun Fung Au: Indiana University
Justin T. Maxwell: Indiana University
Scott M. Robeson: Indiana University
Jinbao Li: The University of Hong Kong
Sacha M. O. Siani: Indiana University
Kimberly A. Novick: Indiana University
Matthew P. Dannenberg: University of Iowa
Richard P. Phillips: Indiana University
Teng Li: Guangzhou University
Zhenju Chen: Shenyang Agricultural University
Jonathan Lenoir: UMR CNRS 7058 ‘Ecologie et Dynamique des Systèmes Anthropisés’ (EDYSAN), Université de Picardie Jules Verne

Nature Climate Change, 2022, vol. 12, issue 12, 1168-1174

Abstract: Abstract As forest demographics are altered by the global decline of old trees and reforestation efforts, younger trees are expected to have an increasingly important influence on carbon sequestration and forest ecosystem functioning. However, the relative resilience of these younger trees to climate change stressors is poorly understood. Here we examine age-dependent drought sensitivity of over 20,000 individual trees across five continents and show that younger trees in the upper canopy layer have larger growth reductions during drought. Angiosperms show greater age differences than gymnosperms, and age-dependent sensitivity is more pronounced in humid climates compared with more arid regions. However, younger canopy-dominant trees also recover more quickly from drought. The future combination of increased drought events and an increased proportion of younger canopy-dominant trees suggests a larger adverse impact on carbon stocks in the short term, while the higher resilience of younger canopy-dominant trees could positively affect carbon stocks over time.

Date: 2022
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DOI: 10.1038/s41558-022-01528-w

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