New insights into the parameterization of the dry surface layer and its hydrogeochemical mechanism: An experimental study

IF 4 2区 环境科学与生态学 Q1 WATER RESOURCES
Fengxia Liu , Hui Qian , Guangcai Wang , Yanyan Gao , Ziwei Shi
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Abstract

Knowledge of the parameterization of the dry surface layer (DSL) is essential for evaluating near-surface water flow and water balance in arid and semi-arid areas. Existing studies have parameterized DSL thickness and vapor flow as functions of the soil moisture content (SMC) in the surface layer to predict soil evaporation. However, hydrochemical processes related to DSL development have been ignored, including changes in hydrochemistry, the underlying hydrochemical mechanism, and the role of dissolved substances in the DSL development. Herein, we performed a series of soil evaporation experiments for 260 days and explored the factors influencing DSL development (e.g., soil texture, atmospheric temperature, SMC, solutes). Evaporation experiments were performed using silty loess, sandy loess, and fine sand with a 60-cm water table. Results showed that the cumulative evaporation of silty loess, sandy loess, and fine sand over the experimental period were 1,391.52, 460.10, and 185.53 mm, respectively, which determined by the maximum height of liquid flow continuity. The content of total dissolved solids (TDS) and major ions at the surface soil were significantly higher than the values at deep depths of 5‒55 cm, which largely depend on evaporative water loss. Evolutionary trends of chemical facies in sand media along the liquid water migration were from HCO3-Ca type to SO4·Cl-Na type. This was attributed to mineral dissolution at a depth of 5–55 cm and their transport with liquid water, resulting in the precipitation of salt crystals at the surface soil. Furthermore, a consolidated DSL with a thickness of 3.0–3.5 cm in the sandy loess and a loose DSL with a thickness of 1.5–2.0 cm in fine sand were observed at the end of the experiments. The accumulation of solutes at the surface leads to a reduction in effective porosity and the aggregation of soil particles during continuous drying, which facilitates the consolidation of DSL in sandy loess. This overestimated the DSL thickness, resulting in a difference between the experimental and predicted evaporation rates by Fick's law. Overall, these results highlight the limitations of considering DSL thickness as a function of SMC only, providing new insights into hydrochemical processes and dissolved solutes involving DSL parameterization during continuous soil drying.

对干燥表层参数化及其水文地球化学机制的新认识:实验研究
干燥表层(DSL)的参数化知识对于评估干旱和半干旱地区的近地表水流和水平衡至关重要。现有研究已将干燥表层厚度和水汽流参数化为表层土壤含水量(SMC)的函数,以预测土壤蒸发。然而,与DSL形成相关的水化学过程却被忽略了,包括水化学的变化、水化学的基本机制以及溶解物质在DSL形成中的作用。在此,我们进行了一系列为期 260 天的土壤蒸发实验,并探讨了影响 DSL 形成的因素(如土壤质地、大气温度、SMC、溶质等)。蒸发实验使用淤泥质黄土、砂质黄土和地下水位为 60 厘米的细砂进行。结果表明,淤泥质黄土、砂质黄土和细砂在实验期间的累计蒸发量分别为 1 391.52 毫米、460.10 毫米和 185.53 毫米,这是由液体流动连续性的最大高度决定的。表层土壤的溶解性总固体(TDS)和主要离子含量明显高于 5-55 厘米深层土壤,这主要取决于蒸发失水。沿着液态水迁移的方向,砂介质中的化学面演变趋势是从 HCO3-Ca 型向 SO4-Cl-Na 型转变。这归因于 5-55 厘米深处的矿物溶解及其随液态水的迁移,导致盐晶体在表层土壤中析出。此外,在实验结束时,还观察到砂质黄土中厚度为 3.0-3.5 厘米的固结 DSL 和细砂中厚度为 1.5-2.0 厘米的松散 DSL。溶质在表层的积累导致有效孔隙度降低,土壤颗粒在持续干燥过程中聚集,从而促进了沙质黄土中 DSL 的固结。这就高估了 DSL 的厚度,导致实验蒸发率与根据菲克定律预测的蒸发率之间存在差异。总之,这些结果凸显了仅将 DSL 厚度视为 SMC 函数的局限性,为连续土壤干燥过程中涉及 DSL 参数化的水化学过程和溶解溶质提供了新的见解。
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来源期刊
Advances in Water Resources
Advances in Water Resources 环境科学-水资源
CiteScore
9.40
自引率
6.40%
发文量
171
审稿时长
36 days
期刊介绍: Advances in Water Resources provides a forum for the presentation of fundamental scientific advances in the understanding of water resources systems. The scope of Advances in Water Resources includes any combination of theoretical, computational, and experimental approaches used to advance fundamental understanding of surface or subsurface water resources systems or the interaction of these systems with the atmosphere, geosphere, biosphere, and human societies. Manuscripts involving case studies that do not attempt to reach broader conclusions, research on engineering design, applied hydraulics, or water quality and treatment, as well as applications of existing knowledge that do not advance fundamental understanding of hydrological processes, are not appropriate for Advances in Water Resources. Examples of appropriate topical areas that will be considered include the following: • Surface and subsurface hydrology • Hydrometeorology • Environmental fluid dynamics • Ecohydrology and ecohydrodynamics • Multiphase transport phenomena in porous media • Fluid flow and species transport and reaction processes
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