loading page

Modeling the Soil Evaporation Loss in Typical Subtropical Secondary Forests-A Changsha Case Study
  • +5
  • Yong Zhang,
  • Xinping Zhang,
  • Xiong Xiao,
  • Junjie Dai,
  • Wanjing Jiang,
  • Zhen Du,
  • Xuhong Zhan,
  • Lu Liu
Yong Zhang
Hunan Normal University
Author Profile
Xinping Zhang
Hunan Normal University
Author Profile
Xiong Xiao
Hunan Normal University

Corresponding Author:xiaoxiong@hunnu.edu.cn

Author Profile
Junjie Dai
Hunan Normal University
Author Profile
Wanjing Jiang
Hunan Normal University
Author Profile
Zhen Du
Hunan Normal University
Author Profile
Xuhong Zhan
Hunan Normal University
Author Profile
Lu Liu
Hunan Normal University
Author Profile

Abstract

Under the more frequent and extreme global drought events, utilizing stable isotopes to quantify soil evaporation losses ( SEL) is of great significance for understanding the water supply capacity from soil to plants. From March 2017 to September 2019, we continuously monitored meteorological factors, soil temperature and humidity, and collected precipitation and soil water stable isotope data. Used the Craig-Gordon (C-G) model and the line-conditioned excess (lc-excess) couple with Rayleigh fractionation (RL) model to quantify SEL in subtropical secondary forests. The results showed: (1) The theoretical Evaporation Line (EL) slope correlated negatively with air temperature ( AT). Water source isotopic values were more positive in autumn and more negative in spring. The aridity index ( AI) and soil evaporation loss ratio ( f) from both models indicated drier conditions from March to September 2018 compared to 2017 and 2019; (2) Comparative analysis showed the C-G model agreed more closely with measured evapotranspiration ( ET0) and water surface evaporation ( E) than the RL model, indicating its better suitability for the study region; (3) Because the “inverse temperature effect” of the precipitation isotopes, the linear fitting method was not suitable for determining the water source in spring, summer, autumn, and on the annual scale, while the EL slope obtained by the fitted slope was consistent with the basic principle of soil evaporation in winter. Thus, the theoretical method was more suitable for determining the EL slope in such regions; (4) because the different fundamentals, the C-G model was positively correlated with air temperature and negatively with relative humidity ( h), while the RL model showed the opposite, indicating different applicability. Meanwhile, SEL is influenced by soil thickness, atmospheric evaporation, and soil water supply capacities. These findings support using stable isotope techniques to quantify SEL and are important for analyzing soil water resources in subtropical secondary forests.
29 Jul 2024Submitted to Hydrological Processes
31 Jul 2024Submission Checks Completed
31 Jul 2024Assigned to Editor
01 Aug 2024Reviewer(s) Assigned
04 Aug 2024Reviewer(s) Assigned
25 Sep 2024Review(s) Completed, Editorial Evaluation Pending
26 Sep 2024Editorial Decision: Revise Major
07 Oct 20241st Revision Received
08 Oct 2024Submission Checks Completed
08 Oct 2024Assigned to Editor
08 Oct 2024Reviewer(s) Assigned
20 Oct 2024Reviewer(s) Assigned
17 Dec 2024Review(s) Completed, Editorial Evaluation Pending
17 Dec 2024Editorial Decision: Revise Minor