Evapotranspiration partitioning through water stable isotopic measurements in a subtropical coniferous forest

IF 2.5 3区环境科学与生态学 Q2 ECOLOGY

Ecohydrology Pub Date : 2024-04-23 DOI:10.1002/eco.2653

Wanqiu Xing, Weiguang Wang, Yue Cai, Zhongbo Yu, Quanxi Shao, Xin Cao, Mingzhu Cao, Lilin Yang, Bin Yong

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Abstract

Evapotranspiration (ET) partitioning distinguishes the soil evaporation (E) and plant transpiration (T) components and is crucial for understanding the land-atmosphere interactions and ecosystem water budget. However, the mechanism and controls of ET partitioning for subtropical forests in heterogeneous environments remain poorly understood. Here, we present δ¹⁸O and δ²H of about 1,527 isotope samples including atmospheric water, soil and plant water during different seasons in 2 years of 2020–2021 from a coniferous forest across Southeast China. We used the isotopic mass balance of ecosystem water pools, the Craig-Gordon model and the Keeling-Plot method to partition T from ET (T/ET) and quantify the controls on T/ET. Results indicated that the uncertainty in the T/ET was principally from the soil water evaporation (δ_E) value, about 20–30 cm was found to be a reasonable evaporating front depth for estimating δ_E in this coniferous forest. T/ET presented a “U” shape diurnal pattern and varied from 66.7% to 89.9%. Isotope-based T/ET in autumn with high temperatures and little rain was higher than those in the summer and winter seasons. Relative humidity (or vapour pressure deficit) dominated the diurnal T/ET variations (relative contributions of > 40%) in summer and autumn, while air temperature and soil water content were the main controls in winter. Our study also showed that δ¹⁸O-derived T/ET was consistent with that of δ²H, although δ²H was found to be more stable in ET partitioning, the dual stable isotope approach should be employed in future studies for the uncertainties brought by samplings or measurements. The agreement between the isotope-based T/ET and ET partitioning approach that uses eddy covariance and sap flux data was stronger at midday. These isotope-inferred ET partitioning can inform land surface models and provide more insights into water management in subtropical forests.

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通过亚热带针叶林中水稳定同位素测量进行蒸散分区

蒸散（ET）分区区分了土壤蒸发（E）和植物蒸腾（T）两部分，对于理解土地-大气相互作用和生态系统水分预算至关重要。然而，人们对异质环境中亚热带森林蒸散发分配的机制和控制仍知之甚少。在此，我们展示了中国东南部针叶林在2020-2021两年不同季节中约1,527个同位素样本的δ18O和δ2H，包括大气水、土壤水和植物水。我们利用生态系统水池同位素质量平衡、Craig-Gordon 模型和 Keeling-Plot 方法从蒸散发（T/ET）中分配 T，并量化 T/ET 的控制因素。结果表明，T/ET 的不确定性主要来自土壤水分蒸发（δE）值，在这片针叶林中，约 20-30 厘米是估算δE 的合理蒸发前沿深度。T/ET呈 "U "型昼夜变化规律，变化范围为 66.7% 至 89.9%。秋季气温高、雨水少，基于同位素的 T/ET 高于夏季和冬季。相对湿度（或蒸汽压力不足）在夏秋季节主导着昼夜 T/ET 变化（相对贡献率大于 40%），而气温和土壤含水量则是冬季的主要控制因素。我们的研究还表明，虽然δ2H 在蒸散发分配中更为稳定，但δ18O 得出的蒸散发总量与δ2H 得出的蒸散发总量是一致的。基于同位素的蒸散发分配法与使用涡度协方差和汁液通量数据的蒸散发分配法在正午时的一致性更强。这些同位素推断的蒸散发分配可以为地表模型提供信息，并为亚热带森林的水资源管理提供更多见解。

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来源期刊

Ecohydrology 环境科学-生态学

CiteScore

5.10

自引率

7.70%

发文量

116

审稿时长

24 months

期刊介绍： Ecohydrology is an international journal publishing original scientific and review papers that aim to improve understanding of processes at the interface between ecology and hydrology and associated applications related to environmental management. Ecohydrology seeks to increase interdisciplinary insights by placing particular emphasis on interactions and associated feedbacks in both space and time between ecological systems and the hydrological cycle. Research contributions are solicited from disciplines focusing on the physical, ecological, biological, biogeochemical, geomorphological, drainage basin, mathematical and methodological aspects of ecohydrology. Research in both terrestrial and aquatic systems is of interest provided it explicitly links ecological systems and the hydrologic cycle; research such as aquatic ecological, channel engineering, or ecological or hydrological modelling is less appropriate for the journal unless it specifically addresses the criteria above. Manuscripts describing individual case studies are of interest in cases where broader insights are discussed beyond site- and species-specific results.