Temperature and water content estimation in soils of the semi-arid region of Brazil using finite difference and CFD

IF 4 2区 农林科学 Q2 SOIL SCIENCE
Daniel Milian Pérez, Abel Gámez Rodríguez, Yaicel Ge Proenza, Antonio Celso Dantas Antonino, José Romualdo de Sousa Lima, Severino Martins dos Santos Neto, Artur Paiva Coutinho, Marcus Metri Correa
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Abstract

Determining the temperature and water content of soil, at a given instant or along time, is fundamental to understand several soil-related phenomena and processes. Evaporation, aeration, chemical-reaction rates and types, biological processes such as germination and growth of seeds, root development, nutrient and water uptake by roots, and decomposition of organic matter by microbes, are all strongly influenced by soil temperature. On the other hand, infiltration of water through the soil surface allows soil to temporarily store water, making it available for uptake by plants and organisms living in soil. Furthermore, soil water content is closely related to physical and chemical properties of soil, such as oxygen content and demand, which impacts root breathing, microbial activity and soil chemical balance. The accurate evaluation of these two parameters and their interconnection is even relevant in semi-arid regions, where climate conditions are particularly difficult, such as the north-eastern zone of Brazil. Thus, the use of computational models and coupled approaches are imperative for rigorous descriptions. This work presents a contribution to estimate soil temperature and water content, by solving the heat transfer equation and the Richards equation, respectively, through finite differences. As input, the model uses the experimental material composition of the soil, the time-dependent temperature profile at the surface and information about the regional rain regime. Three different numerical approaches were implemented: explicit, simple implicit and the Crank–Nicolson method. The calculations for temperature and water content of the soil obtained with these computational models were compared with the results from Computational Fluid Dynamics (CFD). The relative differences between the numerical methods were less than 0.006% by solving the heat transfer equation and less than 2.75% using the Richards equation. The maximum relative differences within the model, including both a constant and a variable water-content profile, were 3.28%. The results from the computational model using the CFX tool have maximum relative differences of 0.6%, which contributes to verifying the accuracy of the implemented methods.

利用有限差分和 CFD 估算巴西半干旱地区土壤的温度和含水量
要了解与土壤有关的若干现象和过程,最基本的是要确定特定瞬间或时间段内土壤的温度和含水量。蒸发、通气、化学反应速率和类型、种子发芽和生长等生物过程、根系发育、根系对养分和水分的吸收以及微生物对有机物的分解,都会受到土壤温度的强烈影响。另一方面,水分通过土壤表层渗透,可使土壤暂时储存水分,供生活在土壤中的植物和生物吸收。此外,土壤含水量还与土壤的物理和化学性质密切相关,如含氧量和需氧量,这对根系呼吸、微生物活动和土壤化学平衡都有影响。在气候条件特别恶劣的半干旱地区,如巴西东北部地区,甚至需要对这两个参数及其相互联系进行准确评估。因此,必须使用计算模型和耦合方法进行严格描述。本研究通过有限差分分别求解传热方程和理查兹方程,对估算土壤温度和含水量做出了贡献。作为输入,该模型使用了土壤的实验材料成分、地表随时间变化的温度曲线以及有关区域降雨机制的信息。模型采用了三种不同的数值方法:显式法、简单隐式法和 Crank-Nicolson 法。利用这些计算模型获得的土壤温度和含水量计算结果与计算流体动力学(CFD)的结果进行了比较。通过求解传热方程,数值方法之间的相对差异小于 0.006%,而使用理查兹方程则小于 2.75%。模型内的最大相对差异为 3.28%,包括恒定和可变水含量曲线。使用 CFX 工具计算模型得出的结果最大相对差异为 0.6%,这有助于验证所实施方法的准确性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
European Journal of Soil Science
European Journal of Soil Science 农林科学-土壤科学
CiteScore
8.20
自引率
4.80%
发文量
117
审稿时长
5 months
期刊介绍: The EJSS is an international journal that publishes outstanding papers in soil science that advance the theoretical and mechanistic understanding of physical, chemical and biological processes and their interactions in soils acting from molecular to continental scales in natural and managed environments.
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