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

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

doi:10.1002/2017gb005733

Cited by 70 publications

(36 citation statements)

References 66 publications

(107 reference statements)

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“…The discrepancy in those studies could be partly attributed to the different environmental conditions, plant species, planting areas and cultivation methods. Moreover, the significant increasing trend (8.5 × 10 −3 g C kg −1 H 2 O per year) of annual WUE found in this study which may be due to the increased atmospheric CO 2 concentration [17,55,56]. However, the WUE trend was much higher than Sun et al (2018) (7.32 × 10 −4 g C kg −1 H 2 O per year) [30] which may induced by their different data sources.…”

Section: Discussioncontrasting

confidence: 64%

“…Many previous studies have investigated the spatiotemporal changes of WUE. For example, Zhou et al (2017) showed that underlying WUE (GPP × VPD 0.5 /ET) increased slowly during 1901-1975 but increased rapidly from 1976 to 2010 over the world based on terrestrial biosphere models [17]. Tang et al (2014) found that the WUE had a similar latitudinal trend on earth, increasing from the subtropics to about 51 • N and then decreased in higher latitudes [18].…”

Section: Introductionmentioning

confidence: 99%

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Response of Ecosystem Water Use Efficiency to Drought over China during 1982–2015: Spatiotemporal Variability and Resilience

Guo

Sun

Liu

et al. 2019

Forests

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Ecosystem water use efficiency (WUE describes carbon-water flux coupling in terrestrial ecosystems. Understanding response and resilience of WUE to drought are essential for sustainable water resource and ecosystem management under increasing drought risks over China due to climate warming. Here we analyzed the response of ecosystem WUE to drought (spatiotemporal variability and resilience) over China during 1982–2015 based on an evapotranspiration (ET) dataset based on the model tree ensemble (MTE) algorithm using flux-tower ET measurements and satellite-retrieved GPP data. The results showed that the multiyear average WUE was 1.55 g C kg−1 H2O over China. WUE increased in 77.1% of Chinese territory during the past 34 years. During drought periods, the ecosystem WUE increased mainly in the northeast of Inner Mongolia, Northeast China and some regions in southern China with abundant forests but decreased in northwestern and central China. An apparent lagging effect of drought on ecosystem WUE was observed in the east of Inner Mongolia and Northeast China, the west and east regions of North China and the central part of Tibetan Plateau. Some ecosystems (e.g., deciduous needle-leaf forests, deciduous broadleaf forests, evergreen broadleaf forests and evergreen needle-leaf forests) in Central China, Northeast and Southwest China exhibited relatively greater resilience to drought than others by improving their WUE. Our findings would provide useful information for Chinese government to adopt a reasonable approach for maintaining the structure and functions of ecosystems under drought disturbance in future.

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Section: Discussioncontrasting

confidence: 64%

Section: Introductionmentioning

confidence: 99%

Response of Ecosystem Water Use Efficiency to Drought over China during 1982–2015: Spatiotemporal Variability and Resilience

Guo

Sun

Liu

et al. 2019

Forests

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“…Increased WUE in forests under eCO 2 has been reported in many previous studies, including those using field experiments (De Kauwe et al, ; Leakey et al, ), tree ring measurements (Dekker et al, ; D. C. Frank et al, ; Saurer et al, ), isotopic compositions of atmospheric CO 2 (Keeling et al, ), eddy covariance (EC) flux tower measurements (Keenan et al, ; Mastrotheodoros et al, ) and model simulations (Cheng et al, ; Huang et al, ; Zhou et al, ). However, these studies have not consistently agreed with the statement that increased WUE under eCO 2 should correspond to increased carbon assimilation and/or decreased water losses in forests.…”

Section: Introductionmentioning

confidence: 75%

Forest‐Type‐Dependent Water Use Efficiency Trends Across the Northern Hemisphere

Wang

Chen

et al. 2018

Geophysical Research Letters

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Changing climate and increasing atmospheric CO2 significantly regulate forest water use efficiency (WUE). However, magnitudes of the WUE trends and underlying processes driving these patterns in two major forest types, deciduous broadleaf forests (DBFs) and evergreen needleleaf forests (ENFs), across the Northern Hemisphere remain poorly understood. We investigated the WUE trends over the past two decades using eddy covariance observations from 26 forest sites from the FLUXNET2015 data set. Our analyses revealed a greater increase in WUE in DBFs than that in ENFs. The decreased stomatal conductance (Gs) mostly contributed to the increase in WUE in the DBFs, whereas the increased gross ecosystem productivity acted as the main trigger for the increase in WUE in the ENFs. The vapor pressure deficit substantially increased in the DBFs, triggering the decrease in Gs. In contrast, the slight CO2 fertilization and the limited stomatal constraint contributed to the increased gross ecosystem productivity in the ENFs.

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“…; Zhou et al . ). Land‐cover change can alter ecosystem water‐use efficiency, for example, by changing the balance between C 3 and C 4 vegetation, by replacing annual with perennial species, or by changing canopy structure and leaf area index in such a way that it impacts the partitioning between evaporation and transpiration at the ecosystem level (Nosetto et al .…”

Section: Gas Exchange and Water‐use Efficiency In Response To Global mentioning

confidence: 99%

“…Recent estimates suggest that the overall contribution of land‐cover change since 1900 has been to reduce water‐use efficiency of terrestrial ecosystems, on average, compared to what it would be in the absence of land‐cover change (Zhou et al . ).…”

Section: Gas Exchange and Water‐use Efficiency In Response To Global mentioning

confidence: 99%

Gas exchange and water‐use efficiency in plant canopies

Cernusak

2018

Plant Biol J

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In this review, I first address the basics of gas exchange, water-use efficiency and carbon isotope discrimination in C 3 plant canopies. I then present a case study of wateruse efficiency in northern Australian tree species. In general, C 3 plants face a trade-off whereby increasing stomatal conductance for a given set of conditions will result in a higher CO 2 assimilation rate, but a lower photosynthetic water-use efficiency. A common garden experiment suggested that tree species which are able to establish and grow in drier parts of northern Australia have a capacity to use water rapidly when it is available through high stomatal conductance, but that they do so at the expense of low water-use efficiency. This may explain why community-level carbon isotope discrimination does not decrease as steeply with decreasing rainfall on the North Australian Tropical Transect as has been observed on some other precipitation gradients. Next, I discuss changes in water-use efficiency that take place during leaf expansion in C 3 plant leaves. Leaf phenology has recently been recognised as a significant driver of canopy gas exchange in evergreen forest canopies, and leaf expansion involves changes in both photosynthetic capacity and water-use efficiency. Following this, I discuss the role of woody tissue respiration in canopy gas exchange and how photosynthetic refixation of respired CO 2 can increase whole-plant water-use efficiency. Finally, I discuss the role of water-use efficiency in driving terrestrial plant responses to global change, especially the rising concentration of atmospheric CO 2 . In coming decades, increases in plant water-use efficiency caused by rising CO 2 are likely to partially mitigate impacts on plants of drought stress caused by global warming.

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

Cited by 70 publications

References 66 publications

Response of Ecosystem Water Use Efficiency to Drought over China during 1982–2015: Spatiotemporal Variability and Resilience

Response of Ecosystem Water Use Efficiency to Drought over China during 1982–2015: Spatiotemporal Variability and Resilience

Forest‐Type‐Dependent Water Use Efficiency Trends Across the Northern Hemisphere

Gas exchange and water‐use efficiency in plant canopies

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