Gross primary production responses to warming, elevated CO2, and irrigation: quantifying the drivers of ecosystem physiology in a semiarid grassland

Edmund M. Ryan; Kiona Ogle; Drew Peltier; Anthony P. Walker; Martin G. De Kauwe; Belinda E. Medlyn; David G. Williams; William Parton; Shinichi Asao; Bertrand Guenet; Anna B. Harper; Xingjie Lu; Kristina A. Luus; Sönke Zaehle; Shijie Shu; Christian Werner; Jianyang Xia; Elise Pendall

doi:10.1111/gcb.13602

Gross primary production responses to warming, elevated CO₂, and irrigation: quantifying the drivers of ecosystem physiology in a semiarid grassland

Edmund M. Ryan^*
, Kiona Ogle
, Drew Peltier
, Anthony P. Walker
, Martin G. De Kauwe
, Belinda E. Medlyn
, David G. Williams
, William Parton
, Shinichi Asao
, Bertrand Guenet
, Anna B. Harper
, Xingjie Lu
, Kristina A. Luus
, Sönke Zaehle
, Shijie Shu
, Christian Werner
, Jianyang Xia
, Elise Pendall

^*此作品的通讯作者

生态与环境科学学院

科研成果: 期刊稿件 › 文章 › 同行评审

42 引用（Scopus）

摘要

Determining whether the terrestrial biosphere will be a source or sink of carbon (C) under a future climate of elevated CO₂ (eCO₂) and warming requires accurate quantification of gross primary production (GPP), the largest flux of C in the global C cycle. We evaluated 6 years (2007–2012) of flux-derived GPP data from the Prairie Heating and CO₂ Enrichment (PHACE) experiment, situated in a grassland in Wyoming, USA. The GPP data were used to calibrate a light response model whose basic formulation has been successfully used in a variety of ecosystems. The model was extended by modeling maximum photosynthetic rate (A_max) and light-use efficiency (Q) as functions of soil water, air temperature, vapor pressure deficit, vegetation greenness, and nitrogen at current and antecedent (past) timescales. The model fits the observed GPP well (R² = 0.79), which was confirmed by other model performance checks that compared different variants of the model (e.g. with and without antecedent effects). Stimulation of cumulative 6-year GPP by warming (29%, P = 0.02) and eCO₂ (26%, P = 0.07) was primarily driven by enhanced C uptake during spring (129%, P = 0.001) and fall (124%, P = 0.001), respectively, which was consistent across years. Antecedent air temperature (Tair_ant) and vapor pressure deficit (VPD_ant) effects on A_max (over the past 3–4 days and 1–3 days, respectively) were the most significant predictors of temporal variability in GPP among most treatments. The importance of VPD_ant suggests that atmospheric drought is important for predicting GPP under current and future climate; we highlight the need for experimental studies to identify the mechanisms underlying such antecedent effects. Finally, posterior estimates of cumulative GPP under control and eCO₂ treatments were tested as a benchmark against 12 terrestrial biosphere models (TBMs). The narrow uncertainties of these data-driven GPP estimates suggest that they could be useful semi-independent data streams for validating TBMs.

源语言	英语
页（从-至）	3092-3106
页数	15
期刊	Global Change Biology
卷	23
期	8
DOI	https://doi.org/10.1111/gcb.13602
出版状态	已出版 - 8月 2017

联合国可持续发展目标

此成果有助于实现下列可持续发展目标：

可持续发展目标 13 气候行动
可持续发展目标 15 陆地生物

访问文件

10.1111/gcb.13602

其它文件与链接

链接到 Scopus 的出版物

引用此

Ryan, E. M., Ogle, K., Peltier, D., Walker, A. P., De Kauwe, M. G., Medlyn, B. E., Williams, D. G., Parton, W., Asao, S., Guenet, B., Harper, A. B., Lu, X., Luus, K. A., Zaehle, S., Shu, S., Werner, C., Xia, J., & Pendall, E. (2017). Gross primary production responses to warming, elevated CO₂, and irrigation: quantifying the drivers of ecosystem physiology in a semiarid grassland. Global Change Biology, 23(8), 3092-3106. https://doi.org/10.1111/gcb.13602

@article{be0e39e879624d47bb6f9a2f7e9c860f,

title = "Gross primary production responses to warming, elevated CO2, and irrigation: quantifying the drivers of ecosystem physiology in a semiarid grassland",

abstract = "Determining whether the terrestrial biosphere will be a source or sink of carbon (C) under a future climate of elevated CO2 (eCO2) and warming requires accurate quantification of gross primary production (GPP), the largest flux of C in the global C cycle. We evaluated 6 years (2007–2012) of flux-derived GPP data from the Prairie Heating and CO2 Enrichment (PHACE) experiment, situated in a grassland in Wyoming, USA. The GPP data were used to calibrate a light response model whose basic formulation has been successfully used in a variety of ecosystems. The model was extended by modeling maximum photosynthetic rate (Amax) and light-use efficiency (Q) as functions of soil water, air temperature, vapor pressure deficit, vegetation greenness, and nitrogen at current and antecedent (past) timescales. The model fits the observed GPP well (R2 = 0.79), which was confirmed by other model performance checks that compared different variants of the model (e.g. with and without antecedent effects). Stimulation of cumulative 6-year GPP by warming (29\%, P = 0.02) and eCO2 (26\%, P = 0.07) was primarily driven by enhanced C uptake during spring (129\%, P = 0.001) and fall (124\%, P = 0.001), respectively, which was consistent across years. Antecedent air temperature (Tairant) and vapor pressure deficit (VPDant) effects on Amax (over the past 3–4 days and 1–3 days, respectively) were the most significant predictors of temporal variability in GPP among most treatments. The importance of VPDant suggests that atmospheric drought is important for predicting GPP under current and future climate; we highlight the need for experimental studies to identify the mechanisms underlying such antecedent effects. Finally, posterior estimates of cumulative GPP under control and eCO2 treatments were tested as a benchmark against 12 terrestrial biosphere models (TBMs). The narrow uncertainties of these data-driven GPP estimates suggest that they could be useful semi-independent data streams for validating TBMs.",

keywords = "Bayesian modeling, carbon cycle, elevated CO, grasslands, gross primary production, multifactor global change experiment, warming",

author = "Ryan, \{Edmund M.\} and Kiona Ogle and Drew Peltier and Walker, \{Anthony P.\} and \{De Kauwe\}, \{Martin G.\} and Medlyn, \{Belinda E.\} and Williams, \{David G.\} and William Parton and Shinichi Asao and Bertrand Guenet and Harper, \{Anna B.\} and Xingjie Lu and Luus, \{Kristina A.\} and S{\"o}nke Zaehle and Shijie Shu and Christian Werner and Jianyang Xia and Elise Pendall",

note = "Publisher Copyright: {\textcopyright} 2017 John Wiley \& Sons Ltd",

year = "2017",

month = aug,

doi = "10.1111/gcb.13602",

language = "英语",

volume = "23",

pages = "3092--3106",

journal = "Global Change Biology",

issn = "1354-1013",

publisher = "Wiley-Blackwell Publishing Ltd",

number = "8",

}

Ryan, EM, Ogle, K, Peltier, D, Walker, AP, De Kauwe, MG, Medlyn, BE, Williams, DG, Parton, W, Asao, S, Guenet, B, Harper, AB, Lu, X, Luus, KA, Zaehle, S, Shu, S, Werner, C, Xia, J & Pendall, E 2017, 'Gross primary production responses to warming, elevated CO₂, and irrigation: quantifying the drivers of ecosystem physiology in a semiarid grassland', Global Change Biology, 卷 23, 号码 8, 页码 3092-3106. https://doi.org/10.1111/gcb.13602

TY - JOUR

T1 - Gross primary production responses to warming, elevated CO2, and irrigation

T2 - quantifying the drivers of ecosystem physiology in a semiarid grassland

AU - Ryan, Edmund M.

AU - Ogle, Kiona

AU - Peltier, Drew

AU - Walker, Anthony P.

AU - De Kauwe, Martin G.

AU - Medlyn, Belinda E.

AU - Williams, David G.

AU - Parton, William

AU - Asao, Shinichi

AU - Guenet, Bertrand

AU - Harper, Anna B.

AU - Lu, Xingjie

AU - Luus, Kristina A.

AU - Zaehle, Sönke

AU - Shu, Shijie

AU - Werner, Christian

AU - Xia, Jianyang

AU - Pendall, Elise

PY - 2017/8

Y1 - 2017/8

N2 - Determining whether the terrestrial biosphere will be a source or sink of carbon (C) under a future climate of elevated CO2 (eCO2) and warming requires accurate quantification of gross primary production (GPP), the largest flux of C in the global C cycle. We evaluated 6 years (2007–2012) of flux-derived GPP data from the Prairie Heating and CO2 Enrichment (PHACE) experiment, situated in a grassland in Wyoming, USA. The GPP data were used to calibrate a light response model whose basic formulation has been successfully used in a variety of ecosystems. The model was extended by modeling maximum photosynthetic rate (Amax) and light-use efficiency (Q) as functions of soil water, air temperature, vapor pressure deficit, vegetation greenness, and nitrogen at current and antecedent (past) timescales. The model fits the observed GPP well (R2 = 0.79), which was confirmed by other model performance checks that compared different variants of the model (e.g. with and without antecedent effects). Stimulation of cumulative 6-year GPP by warming (29%, P = 0.02) and eCO2 (26%, P = 0.07) was primarily driven by enhanced C uptake during spring (129%, P = 0.001) and fall (124%, P = 0.001), respectively, which was consistent across years. Antecedent air temperature (Tairant) and vapor pressure deficit (VPDant) effects on Amax (over the past 3–4 days and 1–3 days, respectively) were the most significant predictors of temporal variability in GPP among most treatments. The importance of VPDant suggests that atmospheric drought is important for predicting GPP under current and future climate; we highlight the need for experimental studies to identify the mechanisms underlying such antecedent effects. Finally, posterior estimates of cumulative GPP under control and eCO2 treatments were tested as a benchmark against 12 terrestrial biosphere models (TBMs). The narrow uncertainties of these data-driven GPP estimates suggest that they could be useful semi-independent data streams for validating TBMs.

AB - Determining whether the terrestrial biosphere will be a source or sink of carbon (C) under a future climate of elevated CO2 (eCO2) and warming requires accurate quantification of gross primary production (GPP), the largest flux of C in the global C cycle. We evaluated 6 years (2007–2012) of flux-derived GPP data from the Prairie Heating and CO2 Enrichment (PHACE) experiment, situated in a grassland in Wyoming, USA. The GPP data were used to calibrate a light response model whose basic formulation has been successfully used in a variety of ecosystems. The model was extended by modeling maximum photosynthetic rate (Amax) and light-use efficiency (Q) as functions of soil water, air temperature, vapor pressure deficit, vegetation greenness, and nitrogen at current and antecedent (past) timescales. The model fits the observed GPP well (R2 = 0.79), which was confirmed by other model performance checks that compared different variants of the model (e.g. with and without antecedent effects). Stimulation of cumulative 6-year GPP by warming (29%, P = 0.02) and eCO2 (26%, P = 0.07) was primarily driven by enhanced C uptake during spring (129%, P = 0.001) and fall (124%, P = 0.001), respectively, which was consistent across years. Antecedent air temperature (Tairant) and vapor pressure deficit (VPDant) effects on Amax (over the past 3–4 days and 1–3 days, respectively) were the most significant predictors of temporal variability in GPP among most treatments. The importance of VPDant suggests that atmospheric drought is important for predicting GPP under current and future climate; we highlight the need for experimental studies to identify the mechanisms underlying such antecedent effects. Finally, posterior estimates of cumulative GPP under control and eCO2 treatments were tested as a benchmark against 12 terrestrial biosphere models (TBMs). The narrow uncertainties of these data-driven GPP estimates suggest that they could be useful semi-independent data streams for validating TBMs.

KW - Bayesian modeling

KW - carbon cycle

KW - elevated CO

KW - grasslands

KW - gross primary production

KW - multifactor global change experiment

KW - warming

UR - https://www.scopus.com/pages/publications/85017405017

U2 - 10.1111/gcb.13602

DO - 10.1111/gcb.13602

M3 - 文章

C2 - 27992952

AN - SCOPUS:85017405017

SN - 1354-1013

VL - 23

SP - 3092

EP - 3106

JO - Global Change Biology

JF - Global Change Biology

IS - 8

ER -

Gross primary production responses to warming, elevated CO2, and irrigation: quantifying the drivers of ecosystem physiology in a semiarid grassland

摘要

联合国可持续发展目标

访问文件

其它文件与链接

指纹

引用此

Gross primary production responses to warming, elevated CO₂, and irrigation: quantifying the drivers of ecosystem physiology in a semiarid grassland