基于物理的全水域土壤保水曲线热力学模型

IF 1.4 4区 农林科学 Q4 SOIL SCIENCE
A. V. Smagin
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引用次数: 0

摘要

摘要 对土壤保水曲线(WRC)的定量描述仍然是水力学中最紧迫的问题之一,因为它对土壤水和溶解物质迁移的计算机建模以及土壤物理性质热力学概念的发展具有重要意义。本文提出了一个新的 WRC 模型,它是水的热力学势能(压力)与土壤中水的含量在从条件零含水量到最大持水量的整个可能范围内的函数关系。与众所周知的经验类比模型不同,该模型基于保水的基本物理机制,结合了毛细管效应和脱节水压(根据 Derjaguin 的观点)。孔隙度(最大持水量)、毛细管极限上升高度和温度为 105°C 时条件零含水量的标准热力学势能等限制因素被用来证明持水量的确定域、其拐点和缩放的合理性。新模型的分析表达式为指数函数和双曲线函数与土壤含水量参数的组合,很容易进行微分,并可利用 WRC 计算微分水容量、可变相界面、孔径分布与最大现场容量值,以及估算固相的比表面积。利用欧亚大陆一些土壤的主要基因类型和质地类别的平均统计水容量对模型进行了验证,证实该模型与实验数据十分吻合,与参数数量相同的标准经验范-格努赫腾模型相比,该模型能更充分地描述条件零土壤含水量附近的水容量。新模型的基本性质及其对整个含水率范围的良好近似能力为其在土壤物理质量评估和水分传输过程建模方面的广泛应用创造了前景,尤其是在精细分散和高度干燥的干旱土壤中,该模型的近似能力超过了已知的类似经验模型。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Physically Based Thermodynamic Model of the Water Retention Curve of Soils for the Entire Water Range

Physically Based Thermodynamic Model of the Water Retention Curve of Soils for the Entire Water Range

Abstract

Quantitative description of the water retention curve (WRC) of soils remains one of the most pressing problems in hydrophysics due to its importance for computer modeling of the transport of soil water and dissolved substances, as well as for the development of the thermodynamic concept of soil physical properties. A new WRC model is presented as a functional dependence of the thermodynamic potential (pressure) of water and its content in the soil over the entire possible range from conditionally zero water content to the maximum water holding capacity. Unlike well-known empirical analogues, the model is based on fundamental physical mechanisms of water retention, combining the capillary effect and disjoining water pressure (according to Derjaguin). Limitations by porosity (maximum water holding capacity), the height of the limiting capillary rise, and the standard thermodynamic potential of conditionally zero water content at a temperature of 105°C are used to justify the domain of determination of the WRC, its inflection point, and scaling. The analytical expression of the new model as a combination of exponential and hyperbolic functions with the argument of soil water content is easily differentiated and allows to calculate, using the WRC, the differential water capacity, variable phase interface, and pore size distribution with a maximum value of field capacity, and to estimate the specific surface area of the solid phase. Validation of the model using mean statistical WRCs of the main genetic types and textural classes of some soils in Eurasia confirms its good agreement with experimental data with a more adequate description of WRC in the vicinity of conditionally zero soil water content compared to the standard empirical van Genuchten’s model with the same number of parameters. The fundamental nature of the new model and its good approximation ability for the entire range of WRC create the prospect of its diverse use for assessing the physical quality of soils and process modeling of water transfer, especially in finely dispersed and highly drying arid soils, where the approximating capabilities of the model exceed the known empirical analogues.

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来源期刊
Eurasian Soil Science
Eurasian Soil Science 农林科学-土壤科学
CiteScore
2.70
自引率
35.70%
发文量
137
审稿时长
12-24 weeks
期刊介绍: Eurasian Soil Science publishes original research papers on global and regional studies discussing both theoretical and experimental problems of genesis, geography, physics, chemistry, biology, fertility, management, conservation, and remediation of soils. Special sections are devoted to current news in the life of the International and Russian soil science societies and to the history of soil sciences. Since 2000, the journal Agricultural Chemistry, the English version of the journal of the Russian Academy of Sciences Agrokhimiya, has been merged into the journal Eurasian Soil Science and is no longer published as a separate title.
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