Forest water use and water use efficiency at elevated <scp><scp>CO<sub>2</sub></scp></scp>: a model‐data intercomparison at two contrasting temperate forest <scp>FACE</scp> sites

Kauwe, Martin G. De; Medlyn, Belinda E.; Zaehle, Sönke; Walker, Anthony P.; Dietze, Michael C.; Hickler, Thomas; Jain, Atul K.; Luo, Yiqi; Parton, William J.; Prentice, Iain Colin; Smith, Benjamin; Thornton, P. E.; Wang, Shusen; Wang, Ying‐Ping; Wårlind, David; Weng, Ensheng; Crous, Kristine Y.; Ellsworth, David S.; Hanson, Paul J.; Kim, Hyun‐Seok; Warren, Jeffrey M.; Oren, Ram; Norby, Richard J.

doi:10.1111/gcb.12164

Cited by 340 publications

(353 citation statements)

References 97 publications

(126 reference statements)

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“…Other models impose biochemical limitations and indirectly reduce stomatal conductance by reducing A as soil moisture stress increases (the models explicitly scale g w with A; otherwise, water-use efficiency would decrease rather than increase with increased biochemical limitation on A). Neither approach can entirely replicate observations (Damour et al, 2010;Egea et al, 2011;De Kauwe et al, 2013), and possibly both diffusive and biochemical limitations must be considered (Zhou et al, 2013). There is also uncertainty about the form of the soil moisture stress function (Verhoef and Egea, 2014).…”

Section: Accounting For Droughtmentioning

confidence: 99%

Stomatal Function across Temporal and Spatial Scales: Deep-Time Trends, Land-Atmosphere Coupling and Global Models

et al. 2017

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Section: Accounting For Droughtmentioning

confidence: 99%

Stomatal Function across Temporal and Spatial Scales: Deep-Time Trends, Land-Atmosphere Coupling and Global Models

et al. 2017

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“…The changes in WUE found in two forested FACE experiments show increases of ~30% in WUE associated with an increase of ~200ppm in CO 2 . However the Oak Ridge and Duke FACE experiments differed in the cause for the WUE change, with either decreasing (Oak Ridge) or little change in transpiration (Duke) paired with large (Oak Ridge) to moderate (Duke) increases in photosynthesis [52][53][54]. FACE experiments are some of the few direct experiments available to test our understanding of whole ecosystem responses to CO 2 and provide invaluable insight into multiple competing responses within ecosystems including deserts, croplands, and agricultural crops [55].…”

Section: Carbon Dioxidementioning

confidence: 95%

“…To asses the water budget and thus the availably of water to plants we need to not only understand how WUE responds to CO 2 and other factors, but also how transpiration and photosynthesis will change in response to elevated CO 2 independent of one another. Climate models do a reasonable job representing the order of magnitude of changes in WUE found in observations over the historical period at forested sites [12], however it is possible that they are still failing to represent the individual changes in photosynthesis and transpiration [52]. The changes in WUE found in two forested FACE experiments show increases of ~30% in WUE associated with an increase of ~200ppm in CO 2 .…”

Section: Carbon Dioxidementioning

confidence: 98%

“…Experiments that use direct manipulation of atmospheric CO 2 concentrations in the field, called Free Air CO 2 Enrichment experiments (FACE), also find increases in WUE, but do not necessarily see decreases in transpiration [52]. To asses the water budget and thus the availably of water to plants we need to not only understand how WUE responds to CO 2 and other factors, but also how transpiration and photosynthesis will change in response to elevated CO 2 independent of one another.…”

Section: Carbon Dioxidementioning

confidence: 99%

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Plants and Drought in a Changing Climate

Swann¹

2018

Preprint

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Purpose of review Climate is changing in response to rising concentrations of atmospheric CO 2 and it is commonly asserted that this will cause droughts to become more frequent and severe. However, different metrics of drought give diverging estimates of future impacts. I present a summary of the significant yet underappreciated influence that plant stomatal and growth responses to CO 2 have on drought, and highlight new insights into the impacts of drought on plants in a warmer world. Recent findings Plants influence the water availability on land, and thus reduce the duration and intensity of droughts under higher CO 2 conditions. Plants are concurrently more vulnerable to mortality when droughts occur under hotter conditions. Summary The frequency and severity of drought in the future depends on the response of plants to a changing climate-ignoring plant responses leads to over-prediction of drought. Nonetheless, the impact of current frequencies of drought on plants could lead to higher mortality rates in the future as plants must withstand drought stress simultaneously with hotter temperatures.

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“…For example, incorporating an increasing number of processes that influence the C cycle may represent the real-world phenomena more realistically but makes the models more complex and less tractable. MIPs have effectively revealed the extent of the differences between model predictions (Schwalm et al, 2010;Keenan et al, 2012;De Kauwe et al, 2013) but provide limited insights into sources of model differences (see Medlyn et al, 2015). The physical emulators make data assimilation computationally feasible for global C cycle models (Hararuk et al, , 2015 and thus offer the possibility to generate independent yet constrained estimates of global land C sequestration to be compared with the indirect estimate from the airborne fraction of C emission and ocean uptake.…”

Section: Constrained Estimates Of Terrestrial C Sequestrationmentioning

confidence: 99%

Transient dynamics of terrestrial carbon storage: mathematical foundation and its applications

et al. 2017

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Abstract. Terrestrial ecosystems have absorbed roughly 30 % of anthropogenic CO 2 emissions over the past decades, but it is unclear whether this carbon (C) sink will endure into the future. Despite extensive modeling and experimental and observational studies, what fundamentally determines transient dynamics of terrestrial C storage under global change is still not very clear. Here we develop a new framework for understanding transient dynamics of terrestrial C storage through mathematical analysis and numerical experiments. Our analysis indicates that the ultimate force driving ecosystem C storage change is the C storage capacity, which is jointly determined by ecosystem C input (e.g., net primary production, NPP) and residence time. Since both C input and residence time vary with time, the C storage capacity is timedependent and acts as a moving attractor that actual C storage chases. The rate of change in C storage is proportional to the C storage potential, which is the difference between the current storage and the storage capacity. The C storage capacity represents instantaneous responses of the land C cycle to external forcing, whereas the C storage potential represents the internal capability of the land C cycle to influence the C change trajectory in the next time step. The influence happens through redistribution of net C pool changes in a network of pools with different residence times.Moreover, this and our other studies have demonstrated that one matrix equation can replicate simulations of most land C cycle models (i.e., physical emulators). As a result, simulation outputs of those models can be placed into a threedimensional (3-D) parameter space to measure their differences. The latter can be decomposed into traceable components to track the origins of model uncertainty. In addition, the physical emulators make data assimilation computationPublished by Copernicus Publications on behalf of the European Geosciences Union. 146Y. Luo et al.: Land carbon storage dynamics ally feasible so that both C flux-and pool-related datasets can be used to better constrain model predictions of land C sequestration. Overall, this new mathematical framework offers new approaches to understanding, evaluating, diagnosing, and improving land C cycle models.

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Forest water use and water use efficiency at elevated CO₂: a model‐data intercomparison at two contrasting temperate forest FACE sites

Cited by 340 publications

References 97 publications

Stomatal Function across Temporal and Spatial Scales: Deep-Time Trends, Land-Atmosphere Coupling and Global Models

Stomatal Function across Temporal and Spatial Scales: Deep-Time Trends, Land-Atmosphere Coupling and Global Models

Plants and Drought in a Changing Climate

Transient dynamics of terrestrial carbon storage: mathematical foundation and its applications

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Forest water use and water use efficiency at elevated CO2: a model‐data intercomparison at two contrasting temperate forest FACE sites

Cited by 340 publications

References 97 publications

Stomatal Function across Temporal and Spatial Scales: Deep-Time Trends, Land-Atmosphere Coupling and Global Models

Stomatal Function across Temporal and Spatial Scales: Deep-Time Trends, Land-Atmosphere Coupling and Global Models

Plants and Drought in a Changing Climate

Transient dynamics of terrestrial carbon storage: mathematical foundation and its applications

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Product

Resources

About

Forest water use and water use efficiency at elevated CO₂: a model‐data intercomparison at two contrasting temperate forest FACE sites