Increased water-use efficiency and reduced CO2 uptake by plants during droughts at a continental scale

Peters, Wouter; Velde, Ivar R. van der; Schaik, Erik van; Miller, J. B.; Ciais, Philippe; Duarte, Henrique F.; Laan-Luijkx, Ingrid T. van der; Molen, M. K. van der; Scholze, Marko; Schaefer, Kevin; Vidale, Pier Luigi; Verhoef, Anne; Wårlind, David; Zhu, Dan; Tans, Pieter P.; Vaughn, Bruce H.; White, James W. C.

doi:10.1038/s41561-018-0212-7

Cited by 158 publications

(106 citation statements)

References 58 publications

(76 reference statements)

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“…Finally, our results show that increased iWUE driven by higher VPD usually corresponds with a reduced GPP (figures 1(e)-(h)), different from increased iWUE under elevated CO 2 that results from increased GPP. Thus, an increase in iWUE does not necessarily translate into increased carbon uptake as simulated by land surface models (Peters et al 2018) or increased tree growth as reported by tree ring data (Lévesque et al 2014, van der Sleen et al 2015, or in other words, whether higher iWUE corresponds to higher GPP depends on the driver of iWUE changes.…”

Section: Excluding the Co 2 Contamination Effectmentioning

confidence: 98%

“…VPD-effects on iWUE could also partially explain the increasing decoupling of growth and iWUE as observed from tree rings (Andrer-Hayles et al 2011, Peñuelas et al 2011). A VPD-driven increase in iWUE should not increase tree growth, as overall it will likely be accompanied by lower GPP (Peters et al 2018). Finally, our results are relevant for drought monitoring and prediction indices that incorporate information about the difference between potential and actual evapotranspiration (Narasimhan andSrinivasan 2005, Otkin et al 2013), which is largely driven by stomatal conductance during dry periods (Novick et al 2016a).…”

Section: Introductionmentioning

confidence: 98%

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Response of ecosystem intrinsic water use efficiency and gross primary productivity to rising vapor pressure deficit

Zhang

Ficklin

Manzoni

et al. 2019

Environ. Res. Lett.

106

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Elevated vapor pressure deficit (VPD) due to drought and warming is well-known to limit canopy stomatal and surface conductance, but the impacts of elevated VPD on ecosystem gross primary productivity (GPP) are less clear. The intrinsic water use efficiency (iWUE), defined as the ratio of carbon (C) assimilation to stomatal conductance, links vegetation C gain and water loss and is a key determinant of how GPP will respond to climate change. While it is well-established that rising atmospheric CO 2 increases ecosystem iWUE, historic and future increases in VPD caused by climate change and drought are often neglected when considering trends in ecosystem iWUE. Here, we synthesize long-term observations of C and water fluxes from 28 North American FLUXNET sites, spanning eight vegetation types, to demonstrate that ecosystem iWUE increases consistently with rising VPD regardless of changes in soil moisture. Another way to interpret this result is that GPP decreases less than surface conductance with increasing VPD. We also project how rising VPD will impact iWUE into the future. Results vary substantially from one site to the next; in a majority of sites, future increases in VPD (RCP 8.5, highest emission scenario) are projected to increase iWUE by 5%-15% by 2050, and by 10%-35% by the end of the century. The increases in VPD owing to elevated global temperatures could be responsible for a 0.13% year −1 increase in ecosystem iWUE in the future. Our results highlight the importance of considering VPD impacts on iWUE independently of CO 2 impacts.

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Section: Excluding the Co 2 Contamination Effectmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 98%

Response of ecosystem intrinsic water use efficiency and gross primary productivity to rising vapor pressure deficit

Zhang

Ficklin

Manzoni

et al. 2019

Environ. Res. Lett.

106

View full text Add to dashboard Cite

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“…The expected effect of elevated [CO 2 ] on tree photosynthesis and carbon availability (Huang, Bergeron, Denneler, Berninger, & Tardif, ) may differ across environmental conditions and warming (Lévesque, Siegwolf, Saurer, Eilmann, & Rigling, ; Lindner et al, ; Sarris, Siegwolf, & Kӧrner, ). For instance, a substantial number of studies reported declining long‐term tree growth and productivity (Barber, Juday, & Finney, ; Giguère‐Croteau et al, ; Girardin, Bouriaud, et al, ; Girardin, Hogg, et al, ; Lévesque et al, ; Nock et al, ; Silva & Anand, ) due to regional drought or warming‐induced drought (Liang, Leuschner, Dulamsuren, Wagner, & Hauck, ; Linares & Camarero, ; Peñuelas, Canadell, & Ogaya, ; Peters et al, ; Rahman, Islam, Gebrekirstos, & Bräuning, ). For montane and boreal forests, no growth enhancement related to elevated CO 2 was found (Dawes et al, ; Hättenschwiler, Miglietta, Raschi, & Korner, ; Klein et al, ; Sigurdsson, Medhurst, Wallin, Eggertsson, & Linder, ).…”

Section: Introductionmentioning

confidence: 99%

“…For instance, a substantial number of studies reported declining long-term tree growth and productivity (Barber, Juday, & Finney, 2000;Giguère-Croteau et al, 2019;Girardin, Bouriaud, et al, 2016;Lévesque et al, 2014;Nock et al, 2011;Silva & Anand, 2013) due to regional drought or warming-induced drought (Liang, Leuschner, Dulamsuren, Wagner, & Hauck, 2016;Linares & Camarero, 2012;Peñuelas, Canadell, & Ogaya, 2011;Peters et al, 2018;Rahman, Islam, Gebrekirstos, & Bräuning, 2019).…”

mentioning

confidence: 99%

Long‐term physiological and growth responses of Himalayan fir to environmental change are mediated by mean climate

Panthi

Fan

Sleen

et al. 2019

Global Change Biology

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High‐elevation forests are experiencing high rates of warming, in combination with CO2 rise and (sometimes) drying trends. In these montane systems, the effects of environmental changes on tree growth are also modified by elevation itself, thus complicating our ability to predict effects of future climate change. Tree‐ring analysis along an elevation gradient allows quantifying effects of gradual and annual environmental changes. Here, we study long‐term physiological (ratio of internal to ambient CO2, i.e., Ci/Ca and intrinsic water‐use efficiency, iWUE) and growth responses (tree‐ring width) of Himalayan fir (Abies spectabilis) trees in response to warming, drying, and CO2 rise. Our study was conducted along elevational gradients in a dry and a wet region in the central Himalaya. We combined dendrochronology and stable carbon isotopes (δ13C) to quantify long‐term trends in Ci/Ca ratio and iWUE (δ13C‐derived), growth (mixed‐effects models), and evaluate climate sensitivity (correlations). We found that iWUE increased over time at all elevations, with stronger increase in the dry region. Climate–growth relations showed growth‐limiting effects of spring moisture (dry region) and summer temperature (wet region), and negative effects of temperature (dry region). We found negative growth trends at lower elevations (dry and wet regions), suggesting that continental‐scale warming and regional drying reduced tree growth. This interpretation is supported by δ13C‐derived long‐term physiological responses, which are consistent with responses to reduced moisture and increased vapor pressure deficit. At high elevations (wet region), we found positive growth trends, suggesting that warming has favored tree growth in regions where temperature most strongly limits growth. At lower elevations (dry and wet regions), the positive effects of CO2 rise did not mitigate the negative effects of warming and drying on tree growth. Our results raise concerns on the productivity of Himalayan fir forests at low and middle (<3,300 m) elevations as climate change progresses.

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“…Respiration is not as well defined with model choice dependent on the spatiotemporal scale under scrutiny [32][33][34]; and 3. Latent heat and water interact at the leaf level via evapotranspiration and hydrological processes in forests [35,36], with research still advancing our knowledge of this complex interaction [37,38].…”

Section: Introductionmentioning

confidence: 99%

Information Needs of Next-Generation Forest Carbon Models: Opportunities for Remote Sensing Science

Boisvenue

White

2019

Remote Sensing

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Forests are integral to the global carbon cycle, and as a result, the accurate estimation of forest structure, biomass, and carbon are key research priorities for remote sensing science. However, estimating and understanding forest carbon and its spatiotemporal variations requires diverse knowledge from multiple research domains, none of which currently offer a complete understanding of forest carbon dynamics. New large-area forest information products derived from remotely sensed data provide unprecedented spatial and temporal information about our forests, which is information that is currently underutilized in forest carbon models. Our goal in this communication is to articulate the information needs of next-generation forest carbon models in order to enable the remote sensing community to realize the best and most useful application of its science, and perhaps also inspire increased collaboration across these research fields. While remote sensing science currently provides important contributions to large-scale forest carbon models, more coordinated efforts to integrate remotely sensed data into carbon models can aid in alleviating some of the main limitations of these models; namely, low sample sizes and poor spatial representation of field data, incomplete population sampling (i.e., managed forests exclusively), and an inadequate understanding of the processes that influence forest carbon accumulation and fluxes across spatiotemporal scales. By articulating the information needs of next-generation forest carbon models, we hope to bridge the knowledge gap between remote sensing experts and forest carbon modelers, and enable advances in large-area forest carbon modeling that will ultimately improve estimates of carbon stocks and fluxes.

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Increased water-use efficiency and reduced CO2 uptake by plants during droughts at a continental scale

Cited by 158 publications

References 58 publications

Response of ecosystem intrinsic water use efficiency and gross primary productivity to rising vapor pressure deficit

Response of ecosystem intrinsic water use efficiency and gross primary productivity to rising vapor pressure deficit

Long‐term physiological and growth responses of Himalayan fir to environmental change are mediated by mean climate

Information Needs of Next-Generation Forest Carbon Models: Opportunities for Remote Sensing Science

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