Evapotranspiration and its driving mechanism of an oasis-desert ecotone ecosystem in arid regions

doi:10.7522/j.issn.1000-694X.2025.00344

Journal of Desert Research ›› 2026, Vol. 46 ›› Issue (1): 74-82.DOI: 10.7522/j.issn.1000-694X.2025.00344

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Evapotranspiration and its driving mechanism of an oasis-desert ecotone ecosystem in arid regions

Xibin Ji¹(), Bowen Jin¹, Wenyue Zhao¹^,², Hai Zhou¹, Rui Chen¹^,², Dongsheng Li¹^,², Liwen Zhao¹, Wenzhi Zhao¹

^1.State Key Laboratory of Ecological Safety and Sustainable Development in Arid Lands / Linze Inland River Basin Research Station，?Northwest Institute of Eco-Environment and Resources，?Chinese Academy of Sciences，Lanzhou 730000，China
^2.University of Chinese Academy of Sciences，Beijing 100049，China

Received:2025-10-10 Revised:2025-12-25 Online:2026-01-20 Published:2026-03-09

Abstract

Abstract:

Evapotranspiration is large enough to be a very important component of water budget in the desert-oasis ecotone in arid regions. A better understanding of the evapotranspiration processes and its driving mechanisms is of insightful significance for protecting the stability of vegetation in the ecotone. Here within a physically based framework describing vapor transfer between the underlying surface and atmosphere， the controls of energy and vapor transfer on evapotranspiration over the underlying surface are determined quantitatively from observations of eddy covariance， micrometeorology， and vegetation dynamics. Rainfall events and vegetation dynamics relieved significantly water stress of the underlying surface， even so， the underlying surface was highly coupled with atmosphere given small decoupling coefficient （e.g.， 0.14）. The equilibrium and imposed components contributed 65% and 35% of the gross evapotranspiration， respectively. Surface conductance exerted an overwhelming control of evapotranspiration rate， which can explain nearly 70% of the variation in daily evapotranspiration. The annual accumulated evapotranspiration （i.e.， 218 mm） exceeded the corresponding precipitation （i.e.， 89 mm） by around 129 mm， suggesting that groundwater plays a pivotal role in sustaining vegetation growth in the ecotone， and keeping groundwater level fluctuating within a narrow range of values is consequently a high priority for conserving vegetation in this ecotone.

Key words: evapotranspiration, surface conductance, decoupling coefficient, water budget, groundwater

CLC Number:

P426.2

Xibin Ji, Bowen Jin, Wenyue Zhao, Hai Zhou, Rui Chen, Dongsheng Li, Liwen Zhao, Wenzhi Zhao. Evapotranspiration and its driving mechanism of an oasis-desert ecotone ecosystem in arid regions[J]. Journal of Desert Research, 2026, 46(1): 74-82.

Figures/Tables 5

Fig.1 Location of the study site

Fig.2 Variation in daily evapotranspiration （ET）， precipitation （P）， and leaf area index （LAI） in the desert-oasis ecotone

Fig.3 Interrelations between daily evapotranspiration and key driving environmental factors and surface conductance during the growth season of vegetation （ET， Rn， VPD， θ， Ep， gs denote daily evapotranspiration， mean daytime net radiation， vapor pressure deficit， soil moisture， potential evapotranspiration， surface conductance， respectively； the bold black lines represent linear regression line between daily evapotranspiration and environmental factors and surface conductance （P<0.05））

Fig.4 Daily average aerodynamic conductance （ga）， surface conductance （gs）， and decoupling coefficient （Ω） during the growth seasons

Fig.5 Daily average equilibrium （λEeq）， imposed latent heat （λEimp）， and the equilibrium （ΩλEeq）， imposed （（1-Ω） λEimp） components of latent heat during the growth season

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Evapotranspiration and its driving mechanism of an oasis-desert ecotone ecosystem in arid regions

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