“Two water worlds” hypothesis: advances and future prospects

doi:10.17521/cjpe.2025.0070

Abstract

Abstract:

Recent advances in stable isotope techniques, in-situ monitoring devices, and soil water extraction methods have increasingly supported the ecohydrological separation phenomenon: plants and streams appear to use water from different soil reservoirs and return it to the hydrosphere. This review summarizes the evolution of the “Two water worlds” (TWW) hypothesis since its initial proposal and discusses the latest research progress, particularly in small-scale field experiments, cross-scale analyses, and cross-ecosystem comparisons. We systematically review the mechanisms and spatiotemporal dynamics underlying the separation of bound water and mobile water in the soil. We also discuss the connectivity between these water pools under various environmental conditions. Key issues, including identifying plant water source, standardizing soil water sampling methods, and addressing model uncertainty, are examined. Future research should focus on investigating plant water uptake mechanisms, improving water stable isotope monitoring techniques, integrating ecohydrological separation processes into hydrological models, and conducting cross-regional comparative studies. This study seeks to improve the accuracy of assessing the coupling between vegetation water use and runoff formation, offering a process-interpretable basis for ecological restoration and watershed management.

Key words: ecohydrological separation, “Two water worlds” hypothesis, bound water, mobile water, stable isotope, plant water source identification

YANG Hao-Lin, ZHAO Ying, HU Qiu-Li, Jeffrey John MCDONNELL. “Two water worlds” hypothesis: advances and future prospects[J]. Chin J Plant Ecol, 2025, 49(9): 1344-1362.

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https://www.plant-ecology.com/EN/Y2025/V49/I9/1344

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References 78

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方法 Method	水分类型 Types of water	缺点 Disadvantage
低温真空抽提法 Cryogenic vacuum extraction	土壤中全部水分 All moisture in the soil	真空、加热条件, 存在分馏 The occurrence of isotopic fractionation under vacuum and heating conditions
离心法 Centrifugation	特定吸力下的水分 Water content at a specific suction level	无法提取小孔隙水 Inability to extract water from small soil pores
共沸蒸馏法 Azeotropic distillation	土壤中全部水分 All moisture in the soil	步骤复杂, 存在有机质污染 Complexity in experimental procedure and susceptibility to organic contamination
机械压榨法 Mechanical squeezing	一定压力下的水分 Water content at a given pressure	土壤类型受限, 效率低 Limitations to specific soil types and low extraction efficiency

方法 Method	水分类型 Types of water	缺点 Disadvantage
低温真空抽提法 Cryogenic vacuum extraction	土壤中全部水分 All moisture in the soil	真空、加热条件, 存在分馏 The occurrence of isotopic fractionation under vacuum and heating conditions
离心法 Centrifugation	特定吸力下的水分 Water content at a specific suction level	无法提取小孔隙水 Inability to extract water from small soil pores
共沸蒸馏法 Azeotropic distillation	土壤中全部水分 All moisture in the soil	步骤复杂, 存在有机质污染 Complexity in experimental procedure and susceptibility to organic contamination
机械压榨法 Mechanical squeezing	一定压力下的水分 Water content at a given pressure	土壤类型受限, 效率低 Limitations to specific soil types and low extraction efficiency