TY - JOUR
T1 - Globally assessing the hysteresis between sub-diurnal actual evaporation and vapor pressure deficit at the ecosystem scale
T2 - Patterns and mechanisms
AU - Xu, Shiqin
AU - McVicar, Tim R.
AU - Li, Lingcheng
AU - Yu, Zhongbo
AU - Jiang, Peng
AU - Zhang, Yuliang
AU - Ban, Zhaoxin
AU - Xing, Wanqiu
AU - Dong, Ningpeng
AU - Zhang, Hua
AU - Zhang, Mingjun
N1 - Funding Information:
This work was funded by the National Natural Science Foundation of China (Grant No. 42101045 ); the Belt and Road Special Foundation of the State Key Laboratory of Hydrology-Water Resources and Hydraulic Engineering (Grant No. 2020490711 and 2021490311 ); and the Foundation for Improving Young Faculty's Scientific Research Capability of Northwest Normal University (Grant No. NWNU-LKQN2021-35 ). TRM was supported by TERN Landscapes ( https://www.tern.org.au/tern-observatory/tern-landscapes/ ), part of Terrestrial Ecosystem Research Network (TERN; https://www.tern.org.au/ ). We thank the editor and three anonymous referees for the detailed and constructive comments.
Publisher Copyright:
© 2022
PY - 2022/8/15
Y1 - 2022/8/15
N2 - Hysteresis between sub-diurnal actual evaporation (AET) (or one of its components, transpiration) and vapor pressure deficit (VPD) at the species or individual ecosystem level has been extensively studied, but the global variation and seasonal variability of this hysteresis across biomes and climates is yet to be fully explored and the limiting mechanisms remain unclear. We hypothesize that the sub-diurnal AET-VPD hysteresis results from the interplay between evaporative demand and soil moisture supply limitations. To test our hypothesis, we quantify the sub-diurnal AET-VPD hysteresis across a broad range of biomes and climates based on the observations from the 89 FLUXNET sites (703 site-years) across the globe. We find that the magnitude of hysteresis varies with biomes and climates and is mostly attributable to evaporative demand limitation in all ten sampled biomes. In seasonally dry locations, however, low soil moisture availability amplifies the hysteresis during the dry season. Sensitivity analysis using a hydraulic model suggests that most ecosystems exhibiting seasonal drought display a more isohydric behavior during the dry season, while shift toward a more anisohydric response during the wet season. Our findings have important implications for understanding sub-diurnal dynamics between vegetation and its surrounding environment, reducing uncertainties in AET simulation at fine spatial and temporal scales, and improving understanding of the ecosystem response to hydrologic stress.
AB - Hysteresis between sub-diurnal actual evaporation (AET) (or one of its components, transpiration) and vapor pressure deficit (VPD) at the species or individual ecosystem level has been extensively studied, but the global variation and seasonal variability of this hysteresis across biomes and climates is yet to be fully explored and the limiting mechanisms remain unclear. We hypothesize that the sub-diurnal AET-VPD hysteresis results from the interplay between evaporative demand and soil moisture supply limitations. To test our hypothesis, we quantify the sub-diurnal AET-VPD hysteresis across a broad range of biomes and climates based on the observations from the 89 FLUXNET sites (703 site-years) across the globe. We find that the magnitude of hysteresis varies with biomes and climates and is mostly attributable to evaporative demand limitation in all ten sampled biomes. In seasonally dry locations, however, low soil moisture availability amplifies the hysteresis during the dry season. Sensitivity analysis using a hydraulic model suggests that most ecosystems exhibiting seasonal drought display a more isohydric behavior during the dry season, while shift toward a more anisohydric response during the wet season. Our findings have important implications for understanding sub-diurnal dynamics between vegetation and its surrounding environment, reducing uncertainties in AET simulation at fine spatial and temporal scales, and improving understanding of the ecosystem response to hydrologic stress.
KW - Canopy-atmosphere coupling
KW - Climate regime and seasonality
KW - Ecosystem-scale isohydricity
KW - Hysteresis index
KW - Water and energy fluxes
UR - http://www.scopus.com/inward/record.url?scp=85134293395&partnerID=8YFLogxK
U2 - 10.1016/j.agrformet.2022.109085
DO - 10.1016/j.agrformet.2022.109085
M3 - Article
AN - SCOPUS:85134293395
SN - 0168-1923
VL - 323
JO - Agricultural and Forest Meteorology
JF - Agricultural and Forest Meteorology
M1 - 109085
ER -