Response of Water Use Efficiency to Global Environmental Change Based on Output From Terrestrial Biosphere Models

Sha Zhou; Bofu Yu; Christopher R. Schwalm; Philippe Ciais; Yao Zhang; Joshua B. Fisher; Anna M. Michalak; Weile Wang; Benjamin Poulter; Deborah N. Huntzinger; Shuli Niu; Jiafu Mao; Atul Jain; Daniel M. Ricciuto; Xiaoying Shi; Akihiko Ito; Yaxing Wei; Yuefei Huang; Guangqian Wang

doi:10.1002/2017GB005733

Response of Water Use Efficiency to Global Environmental Change Based on Output From Terrestrial Biosphere Models

Sha Zhou, Bofu Yu, Christopher R. Schwalm, Philippe Ciais, Yao Zhang, Joshua B. Fisher, Anna M. Michalak, Weile Wang, Benjamin Poulter, Deborah N. Huntzinger, Shuli Niu, Jiafu Mao, Atul Jain, Daniel M. Ricciuto, Xiaoying Shi, Akihiko Ito, Yaxing Wei, Yuefei Huang, Guangqian Wang

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82 Scopus citations

Abstract

Water use efficiency (WUE), defined as the ratio of gross primary productivity and evapotranspiration at the ecosystem scale, is a critical variable linking the carbon and water cycles. Incorporating a dependency on vapor pressure deficit, apparent underlying WUE (uWUE) provides a better indicator of how terrestrial ecosystems respond to environmental changes than other WUE formulations. Here we used 20th century simulations from four terrestrial biosphere models to develop a novel variance decomposition method. With this method, we attributed variations in apparent uWUE to both the trend and interannual variation of environmental drivers. The secular increase in atmospheric CO₂ explained a clear majority of total variation (66 ± 32%: mean ± one standard deviation), followed by positive trends in nitrogen deposition and climate, as well as a negative trend in land use change. In contrast, interannual variation was mostly driven by interannual climate variability. To analyze the mechanism of the CO₂ effect, we partitioned the apparent uWUE into the transpiration ratio (transpiration over evapotranspiration) and potential uWUE. The relative increase in potential uWUE parallels that of CO₂, but this direct CO₂ effect was offset by 20 ± 4% by changes in ecosystem structure, that is, leaf area index for different vegetation types. However, the decrease in transpiration due to stomatal closure with rising CO₂ was reduced by 84% by an increase in leaf area index, resulting in small changes in the transpiration ratio. CO₂ concentration thus plays a dominant role in driving apparent uWUE variations over time, but its role differs for the two constituent components: potential uWUE and transpiration.

Original language	English
Pages (from-to)	1639-1655
Number of pages	17
Journal	Global Biogeochemical Cycles
Volume	31
Issue number	11
DOIs	https://doi.org/10.1002/2017GB005733
State	Published - Nov 2017

Funding

This paper is financially supported by the Research and Development Special Fund for Public Welfare Industry of the Ministry of Water Research in China (201501028). Funding for the Multi-scale synthesis and Terrestrial Model Intercomparison Project (MsTMIP; http://nacp.ornl.gov/MsTMIP.shtml) activity was provided through NASA ROSES grant NNX10AG01A. Data management support for preparing, documenting, and distributing model driver and output data was performed by the Modeling and Synthesis Thematic Data Center at Oak Ridge National Laboratory (ORNL; http://nacp.ornl.gov), with funding through NASA ROSES grant NNH10AN681. Finalized MsTMIP data products are archived at the ORNL DAAC (http://daac.ornl.gov). We also acknowledge the modeling groups that provided results to MsTMIP. Joshua B. Fisher contributed to this manuscript from the Jet Propulsion Laboratory, California Institute of Technology, under a contract with the National Aeronautics and Space Administration. Jiafu Mao, Xiaoying Shi, and Daniel M. Ricciuto are supported by the U.S. Department of Energy (DOE), Office of Science, Biological and Environmental Research. Oak Ridge National Laboratory is managed by UT-BATTELLE for DOE under contract DE-AC05-00OR22725.

Keywords

atmospheric CO
attribution
interannual variability
physiology
structure
trend

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Zhou, S., Yu, B., Schwalm, C. R., Ciais, P., Zhang, Y., Fisher, J. B., Michalak, A. M., Wang, W., Poulter, B., Huntzinger, D. N., Niu, S., Mao, J., Jain, A., Ricciuto, D. M., Shi, X., Ito, A., Wei, Y., Huang, Y., & Wang, G. (2017). Response of Water Use Efficiency to Global Environmental Change Based on Output From Terrestrial Biosphere Models. Global Biogeochemical Cycles, 31(11), 1639-1655. https://doi.org/10.1002/2017GB005733

@article{9246e91a899a4a98900e2090abefdcec,

title = "Response of Water Use Efficiency to Global Environmental Change Based on Output From Terrestrial Biosphere Models",

abstract = "Water use efficiency (WUE), defined as the ratio of gross primary productivity and evapotranspiration at the ecosystem scale, is a critical variable linking the carbon and water cycles. Incorporating a dependency on vapor pressure deficit, apparent underlying WUE (uWUE) provides a better indicator of how terrestrial ecosystems respond to environmental changes than other WUE formulations. Here we used 20th century simulations from four terrestrial biosphere models to develop a novel variance decomposition method. With this method, we attributed variations in apparent uWUE to both the trend and interannual variation of environmental drivers. The secular increase in atmospheric CO2 explained a clear majority of total variation (66 ± 32\%: mean ± one standard deviation), followed by positive trends in nitrogen deposition and climate, as well as a negative trend in land use change. In contrast, interannual variation was mostly driven by interannual climate variability. To analyze the mechanism of the CO2 effect, we partitioned the apparent uWUE into the transpiration ratio (transpiration over evapotranspiration) and potential uWUE. The relative increase in potential uWUE parallels that of CO2, but this direct CO2 effect was offset by 20 ± 4\% by changes in ecosystem structure, that is, leaf area index for different vegetation types. However, the decrease in transpiration due to stomatal closure with rising CO2 was reduced by 84\% by an increase in leaf area index, resulting in small changes in the transpiration ratio. CO2 concentration thus plays a dominant role in driving apparent uWUE variations over time, but its role differs for the two constituent components: potential uWUE and transpiration.",

keywords = "atmospheric CO, attribution, interannual variability, physiology, structure, trend",

author = "Sha Zhou and Bofu Yu and Schwalm, \{Christopher R.\} and Philippe Ciais and Yao Zhang and Fisher, \{Joshua B.\} and Michalak, \{Anna M.\} and Weile Wang and Benjamin Poulter and Huntzinger, \{Deborah N.\} and Shuli Niu and Jiafu Mao and Atul Jain and Ricciuto, \{Daniel M.\} and Xiaoying Shi and Akihiko Ito and Yaxing Wei and Yuefei Huang and Guangqian Wang",

year = "2017",

month = nov,

doi = "10.1002/2017GB005733",

language = "English",

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journal = "Global Biogeochemical Cycles",

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Zhou, S, Yu, B, Schwalm, CR, Ciais, P, Zhang, Y, Fisher, JB, Michalak, AM, Wang, W, Poulter, B, Huntzinger, DN, Niu, S, Mao, J, Jain, A, Ricciuto, DM , Shi, X, Ito, A, Wei, Y, Huang, Y & Wang, G 2017, 'Response of Water Use Efficiency to Global Environmental Change Based on Output From Terrestrial Biosphere Models', Global Biogeochemical Cycles, vol. 31, no. 11, pp. 1639-1655. https://doi.org/10.1002/2017GB005733

TY - JOUR

T1 - Response of Water Use Efficiency to Global Environmental Change Based on Output From Terrestrial Biosphere Models

AU - Zhou, Sha

AU - Yu, Bofu

AU - Schwalm, Christopher R.

AU - Ciais, Philippe

AU - Zhang, Yao

AU - Fisher, Joshua B.

AU - Michalak, Anna M.

AU - Wang, Weile

AU - Poulter, Benjamin

AU - Huntzinger, Deborah N.

AU - Niu, Shuli

AU - Mao, Jiafu

AU - Jain, Atul

AU - Ricciuto, Daniel M.

AU - Shi, Xiaoying

AU - Ito, Akihiko

AU - Wei, Yaxing

AU - Huang, Yuefei

AU - Wang, Guangqian

PY - 2017/11

Y1 - 2017/11

N2 - Water use efficiency (WUE), defined as the ratio of gross primary productivity and evapotranspiration at the ecosystem scale, is a critical variable linking the carbon and water cycles. Incorporating a dependency on vapor pressure deficit, apparent underlying WUE (uWUE) provides a better indicator of how terrestrial ecosystems respond to environmental changes than other WUE formulations. Here we used 20th century simulations from four terrestrial biosphere models to develop a novel variance decomposition method. With this method, we attributed variations in apparent uWUE to both the trend and interannual variation of environmental drivers. The secular increase in atmospheric CO2 explained a clear majority of total variation (66 ± 32%: mean ± one standard deviation), followed by positive trends in nitrogen deposition and climate, as well as a negative trend in land use change. In contrast, interannual variation was mostly driven by interannual climate variability. To analyze the mechanism of the CO2 effect, we partitioned the apparent uWUE into the transpiration ratio (transpiration over evapotranspiration) and potential uWUE. The relative increase in potential uWUE parallels that of CO2, but this direct CO2 effect was offset by 20 ± 4% by changes in ecosystem structure, that is, leaf area index for different vegetation types. However, the decrease in transpiration due to stomatal closure with rising CO2 was reduced by 84% by an increase in leaf area index, resulting in small changes in the transpiration ratio. CO2 concentration thus plays a dominant role in driving apparent uWUE variations over time, but its role differs for the two constituent components: potential uWUE and transpiration.

AB - Water use efficiency (WUE), defined as the ratio of gross primary productivity and evapotranspiration at the ecosystem scale, is a critical variable linking the carbon and water cycles. Incorporating a dependency on vapor pressure deficit, apparent underlying WUE (uWUE) provides a better indicator of how terrestrial ecosystems respond to environmental changes than other WUE formulations. Here we used 20th century simulations from four terrestrial biosphere models to develop a novel variance decomposition method. With this method, we attributed variations in apparent uWUE to both the trend and interannual variation of environmental drivers. The secular increase in atmospheric CO2 explained a clear majority of total variation (66 ± 32%: mean ± one standard deviation), followed by positive trends in nitrogen deposition and climate, as well as a negative trend in land use change. In contrast, interannual variation was mostly driven by interannual climate variability. To analyze the mechanism of the CO2 effect, we partitioned the apparent uWUE into the transpiration ratio (transpiration over evapotranspiration) and potential uWUE. The relative increase in potential uWUE parallels that of CO2, but this direct CO2 effect was offset by 20 ± 4% by changes in ecosystem structure, that is, leaf area index for different vegetation types. However, the decrease in transpiration due to stomatal closure with rising CO2 was reduced by 84% by an increase in leaf area index, resulting in small changes in the transpiration ratio. CO2 concentration thus plays a dominant role in driving apparent uWUE variations over time, but its role differs for the two constituent components: potential uWUE and transpiration.

KW - atmospheric CO

KW - attribution

KW - interannual variability

KW - physiology

KW - structure

KW - trend

UR - https://www.scopus.com/pages/publications/85037972206

U2 - 10.1002/2017GB005733

DO - 10.1002/2017GB005733

M3 - Article

AN - SCOPUS:85037972206

SN - 0886-6236

VL - 31

SP - 1639

EP - 1655

JO - Global Biogeochemical Cycles

JF - Global Biogeochemical Cycles

IS - 11

ER -

Response of Water Use Efficiency to Global Environmental Change Based on Output From Terrestrial Biosphere Models

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