近地表水汽对植被水分补偿及量化研究进展OA
Research progress on moisture compensation of near-surface atmospheric water for vegetation and its quantification in arid environments
在气候变化导致极端干旱频发背景下,近地表大气水(Near-Surface Atmospheric Water,NSAW)作为干旱区生态系统的重要隐性水源,其介导的水分补偿对缓解植被水分胁迫具有重要意义.然而,目前对于NSAW对植被水分的补偿过程、补偿机理、补偿权重及相关的量化方法仍需要进一步明确.基于此,本文对NSAW水文过程和生态作用机理、NSAW对植被与土壤水分补偿机制及NSAW相变量化方法进行了研究进展综述.已有的重要研究成果包括:植被主要通过气孔、角质层或特有结构等直接吸收利用NSAW,这种方式在植被获取NSAW水分过程中占主导地位;NSAW水分经由土壤吸湿或液化,通过根系水力再分配(HR)过程间接调节植被水分,形成新的水分平衡;在NSAW相变量化和模拟方面,微气象监测与稳定同位素技术相结合,实现了对NSAW的动态观测和水分来源的高精度解析.由于缺乏材料物理学特性相关参数,尤其是热力学参数,有关NSAW水分相变的量化难以形成共识,如叶片吸收气态水的效率参数缺失、多尺度耦合模型缺乏等.基于已有研究成果,本文认为未来需重点突破NSAW—碳同化耦合效应及多源数据协同监测技术开发、多尺度动态模型构建,可为旱区水资源高效利用提供理论依据.
Near-surface atmospheric water(NSAW)serves as an important hidden water source in arid-zone eco-systems,where its role in mediating water compensation is key to alleviating vegetation water stress amid the in-creasing frequency of extreme droughts driven by climate change.However,the compensation process,underly-ing mechanisms,weighting schemes,and quantification methods associated with NSAW and vegetation water re-main to be further clarified.Therefore,this paper reviews the research progress on the hydrological processes and functional mechanisms of NSAW,the compensation mechanisms of NSAW for vegetation and soil moisture,and the quantification methods for phase transformation of NSAW.Existing research findings indicate that vegetation can absorb and utilize NSAW water through stomata,cuticles,or specialized structures,and this pathway predom-inantly governs the process by which vegetation acquires NSAW water.NSAW water is absorbed or liquefied by the soil,indirectly regulating vegetation water content through the hydraulic redistribution(HR)process of the root system and thereby establishing a new moisture balance.Dynamic observations of NSAW,along with high-precision analysis of water sources,have been achieved through the integration of micrometeorological monitor-ing and stable isotope technology.This approach contributes significantly to the quantification and simulation of phase transformations in the field of NSAW.Nevertheless,reaching a consensus on the quantification of NSAW phase transformation remains challenging owing to the lack of parameters related to the physical properties of ma-terials,particularly thermodynamic parameters.This deficiency results in an absence of data on the efficiency of leaf absorption of gaseous water,as well as a shortage of multiscale coupling models.In conclusion,this review posits that future investigations should focus on achieving breakthroughs in the coupling effects of NSAW and carbon assimilation,the development of collaborative monitoring technologies utilizing multisource data,and the construction of multiscale dynamic models.These advancements are expected to provide a theoretical foundation for the efficient utilization of water resources under arid conditions.
杨艳;张维江;马婷;王磊;马波
宁夏大学土木与水利工程学院,宁夏 银川 750021宁夏大学土木与水利工程学院,宁夏 银川 750021||旱区现代农业水资源高效利用教育部工程研究中心,宁夏 银川 750021宁夏大学土木与水利工程学院,宁夏 银川 750021宁夏大学土木与水利工程学院,宁夏 银川 750021宁夏大学土木与水利工程学院,宁夏 银川 750021||旱区现代农业水资源高效利用教育部工程研究中心,宁夏 银川 750021
近地表大气水叶片吸水水分补偿水力再分配
near-surface atmospheric waterleaf water uptakewater compensationhydraulic redistribution
《干旱区研究》 2026 (5)
943-954,12
宁夏自然科学基金项目(2022AAC02018)宁夏重点研发计划项目(2023BEG02054)宁夏高等学校一流学科建设(水利工程学科)项目(NXYLXK2021A03)
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