To what extent can rising [CO2] ameliorate plant drought stress?

Summary Plant responses to elevated atmospheric carbon dioxide (eCO2) have been hypothesized as a key mechanism that may ameliorate the impact of future drought. Yet, despite decades of experiments, the question of whether eCO2 reduces plant water use, yielding ‘water savings’ that can be used to ma...

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Bibliographic Details
Published in:The New phytologist 2021-09, Vol.231 (6), p.2118-2124
Main Authors: De Kauwe, Martin G., Medlyn, Belinda E., Tissue, David T.
Format: Article
Language:English
Subjects:
Carbon dioxide
Climate models
Drought
drought mortality
dry‐down
elevated CO2
Environmental impact
Leaf area
Moisture content
Soil water
Vapor pressure
Vapour pressure
Water conservation
Water content
water savings
Water stress
Water use
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Summary:Summary Plant responses to elevated atmospheric carbon dioxide (eCO2) have been hypothesized as a key mechanism that may ameliorate the impact of future drought. Yet, despite decades of experiments, the question of whether eCO2 reduces plant water use, yielding ‘water savings’ that can be used to maintain plant function during periods of water stress, remains unresolved. In this Viewpoint, we identify the experimental challenges and limitations to our understanding of plant responses to drought under eCO2. In particular, we argue that future studies need to move beyond exploring whether eCO2 played ‘a role’ or ‘no role’ in responses to drought, but instead more carefully consider the timescales and conditions that would induce an influence. We also argue that considering emergent differences in soil water content may be an insufficient means of assessing the impact of eCO2. We identify eCO2 impact during severe drought (e.g. to the point of mortality), interactions with future changes in vapour pressure deficit and uncertainty about changes in leaf area as key gaps in our current understanding. New insights into CO2 × drought interactions are essential to better constrain model theory that governs future climate model projections of land–atmosphere interactions during periods of water stress.
ISSN:0028-646X
1469-8137
DOI:10.1111/nph.17540