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Main Authors: Caprais, Mathis, Shviro, Oriane, Pensec, Ugo, Zeyen, Hermann
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2405.15284
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author Caprais, Mathis
Shviro, Oriane
Pensec, Ugo
Zeyen, Hermann
author_facet Caprais, Mathis
Shviro, Oriane
Pensec, Ugo
Zeyen, Hermann
contents Modeling underground temperatures provides a practical application of the one-dimensional heat equation. In this work, the one-dimensional heat equation in surface soil is extended to include heat carried by the vertical flow of rainwater through the soil. Analytical solutions, with and without water flow, illustrate the influence of rainwater circulation on the sub-surface propagation of seasonal temperature variations, an important effect that is generally neglected in textbooks. The surface temperature variations are damped by the soil, and this effect was used by the Troglodytae in Egypt or the Petra in South Jordan to insulate against extreme temperatures. For a realistic case of horizontally layered geology, a finite difference Python code was developed for the same purpose. Subsurface temperatures were also measured over a full year at depths up to 1.8 m and used to estimate the thermal skin depth and thermal wavelength. This study provides students with a practical example of how a textbook physics problem can be modified to extract information of contemporary importance in geophysics and global warming.
format Preprint
id arxiv_https___arxiv_org_abs_2405_15284
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Application of the heat equation to the study of underground temperature
Caprais, Mathis
Shviro, Oriane
Pensec, Ugo
Zeyen, Hermann
Geophysics
Modeling underground temperatures provides a practical application of the one-dimensional heat equation. In this work, the one-dimensional heat equation in surface soil is extended to include heat carried by the vertical flow of rainwater through the soil. Analytical solutions, with and without water flow, illustrate the influence of rainwater circulation on the sub-surface propagation of seasonal temperature variations, an important effect that is generally neglected in textbooks. The surface temperature variations are damped by the soil, and this effect was used by the Troglodytae in Egypt or the Petra in South Jordan to insulate against extreme temperatures. For a realistic case of horizontally layered geology, a finite difference Python code was developed for the same purpose. Subsurface temperatures were also measured over a full year at depths up to 1.8 m and used to estimate the thermal skin depth and thermal wavelength. This study provides students with a practical example of how a textbook physics problem can be modified to extract information of contemporary importance in geophysics and global warming.
title Application of the heat equation to the study of underground temperature
topic Geophysics
url https://arxiv.org/abs/2405.15284