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Forest Vulnerability to Drought Controlled by Bedrock Composition

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Forests are increasingly threatened by climate-change-fuelled cycles of drought, dieback and wildfires. However, for reasons that remain incompletely understood, some forest stands are more vulnerable than others, leaving a patchwork of varying dieback and wildfire risk after drought. Here, we show that spatial variability in forest drought response can be explained by differences in underlying bedrock. Our analysis links geochemical measurements of bedrock composition, geophysical measurements of subsurface weathering and remotely sensed changes in evapotranspiration during the 2011–2017 drought in California. We find that evapotranspiration plummeted in dense forest stands rooted in weathered, nutrient-rich bedrock. By contrast, relatively unweathered, nutrient-poor bedrock supported thin forest stands that emerged unscathed from the drought. By influencing both subsurface weathering and nutrient supply, bedrock composition regulates the balance of water storage and demand in mountain ecosystems. However, rather than enhancing forest resilience to drought by providing more water-storage capacity, bedrock with more weatherable and nutrient-rich minerals induced greater vulnerability by enabling a boom–bust cycle in which higher ecosystem productivity during wet years drives excess plant water demand during droughts.

Callahan, Russell P., Clifford S. Riebe, Leonard S. Sklar, Sylvain Pasquet, Ken L. Ferrier, W. Jesse Hahm, Nicholas J. Taylor, Dario Grana, Brady A. Flinchum, Jorden L. Hayes, and W. Steven Holbrook. Forest Vulnerability to Drought Controlled by Bedrock Composition. Nature Geoscience 15, no. 9 (2022): 714-719. https://www.nature.com/articles/s41561-022-01012-2

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Jorden Hayes is a professor of Earth Sciences at Dickinson College.

For more information on the published version, visit Springer Nature's Website. https://www.nature.com/articles/s41561-022-01012-2

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  • Nature Geoscience

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MLA citation style (9th ed.)

Callahan, Russell P. , et al. Forest Vulnerability to Drought Controlled by Bedrock Composition. . 2022. dickinson.hykucommons.org/concern/generic_works/af3a026e-36b4-4ae1-b0a2-933d80f050d3?locale=fr.

APA citation style (7th ed.)

C. R. P., R. C. S., H. W. Steven, S. L. S., P. Sylvain, F. K. L., H. W. Jesse, T. N. J., G. Dario, F. B. A., & H. J. L. (2022). Forest Vulnerability to Drought Controlled by Bedrock Composition. https://dickinson.hykucommons.org/concern/generic_works/af3a026e-36b4-4ae1-b0a2-933d80f050d3?locale=fr

Chicago citation style (CMOS 17, author-date)

Callahan, Russell P. , Riebe, Clifford S. , Holbrook, W. Steven , Sklar, Leonard S. , Pasquet, Sylvain , Ferrier, Ken L. , Hahm, W. Jesse et al. Forest Vulnerability to Drought Controlled by Bedrock Composition. 2022. https://dickinson.hykucommons.org/concern/generic_works/af3a026e-36b4-4ae1-b0a2-933d80f050d3?locale=fr.

Note: These citations are programmatically generated and may be incomplete.

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