The global carbon and water cycles are strongly governed by the simultaneous diffusion of CO2 and water vapour through the leaves of terrestrial plants. These diffusive fluxes are controlled by plants’ adaptations to balance carbon gains and hydraulic risks. We introduce a trait-based optimality theory that unifies the treatment of stomatal responses and biochemical acclimation of plants to changing environments. Tested with experimental data from eighteen species, our model successfully predicts the simultaneous decline in carbon assimilation rate, stomatal conductance, and photosynthetic capacity during progressive soil drought. It also correctly predicts the dependencies of gas exchange on atmospheric vapour pressure deficit, temperature...
Rising levels of atmospheric CO2 concentration (Ca) and simultaneous climate change profoundly affec...
Intrinsic water use efficiency (Wi), the ratio of net CO2 assimilation (A) over stomatal conductance...
Plant physiological adaptation to the global rise in atmospheric CO 2 concentration (CO2) is identif...
The global carbon and water cycles are governed by the coupling of CO2 and water vapour exchanges th...
Close coupling between water loss and carbon dioxide uptake requires coordination of plant hydraulic...
Close coupling between water loss and carbon dioxide uptake requires coordination of plant hydraulic...
Atmospheric aridity and drought both influence physiological function in plant leaves, but their rel...
It's commonly accepted that the universal trade-off between water saving and CO2 capture driven by s...
Optimal stomatal theory predicts that stomata operate to maximise photosynthesis (Anet) and minimise...
Leaf water potential regulation is a key process in whole plant and ecosystem functioning. While low...
Tight coordination in the photosynthetic, gas exchange and water supply capacities of leaves is a gl...
The classical theory of stomatal optimization stipulates that stomata should act to maximize photosy...
Understanding stomatal regulation during drought is essential to correctly predict vegetation-atmosp...
Stomatal conductance links plant water use and carbon uptake. Its responses to environmental conditi...
Leaf transpiration rate (E) frequently shows a peaked response to increasing vapour pressure deficit...
Rising levels of atmospheric CO2 concentration (Ca) and simultaneous climate change profoundly affec...
Intrinsic water use efficiency (Wi), the ratio of net CO2 assimilation (A) over stomatal conductance...
Plant physiological adaptation to the global rise in atmospheric CO 2 concentration (CO2) is identif...
The global carbon and water cycles are governed by the coupling of CO2 and water vapour exchanges th...
Close coupling between water loss and carbon dioxide uptake requires coordination of plant hydraulic...
Close coupling between water loss and carbon dioxide uptake requires coordination of plant hydraulic...
Atmospheric aridity and drought both influence physiological function in plant leaves, but their rel...
It's commonly accepted that the universal trade-off between water saving and CO2 capture driven by s...
Optimal stomatal theory predicts that stomata operate to maximise photosynthesis (Anet) and minimise...
Leaf water potential regulation is a key process in whole plant and ecosystem functioning. While low...
Tight coordination in the photosynthetic, gas exchange and water supply capacities of leaves is a gl...
The classical theory of stomatal optimization stipulates that stomata should act to maximize photosy...
Understanding stomatal regulation during drought is essential to correctly predict vegetation-atmosp...
Stomatal conductance links plant water use and carbon uptake. Its responses to environmental conditi...
Leaf transpiration rate (E) frequently shows a peaked response to increasing vapour pressure deficit...
Rising levels of atmospheric CO2 concentration (Ca) and simultaneous climate change profoundly affec...
Intrinsic water use efficiency (Wi), the ratio of net CO2 assimilation (A) over stomatal conductance...
Plant physiological adaptation to the global rise in atmospheric CO 2 concentration (CO2) is identif...