Heated fibre optics to monitor soil moisture under successive saturation–drying cycles: An experimental approach

IF 4 2区 农林科学 Q2 SOIL SCIENCE
Luis Eduardo Bertotto, Alan Reis, Érick Rúbens Oliveira Cobalchini, Dimaghi Schwamback, José Gescilam Sousa Mota Uchôa, Edson Cezar Wendland
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引用次数: 0

Abstract

In recent decades, distributed temperature sensing (DTS) has emerged as a robust technology for environmental applications, enabling high-resolution temperature measurements along fibre optic cables (FOCs). The actively heated fibre optic (AHFO) method is employed to monitor soil moisture ( θ $$ \theta $$ , m3 m−3), wherein the soil temperature subsequent to the application of a heat pulse is measured by a DTS (AHFO-DTS approach). Despite significant improvements in the application of AHFO-DTS under controlled and natural conditions, the thermal behaviour of soil during multiple saturation–natural drying cycles has been insufficiently evaluated. This study aimed to address this gap by constructing an experimental horizontal soil profile in the laboratory for the application of the AHFO-DTS method during two successive saturation–drainage–evaporation (SDE) cycles. Three heating strategies were applied to a metallic alloy in contact with a FOC, and calibration models were used to correlate θ $$ \theta $$ with the thermal conductivity ( λ $$ \lambda $$ ), cumulative temperature increase ( T cum $$ {T}_{\mathrm{cum}} $$ ), and maximum temperature increase ( T max $$ {T}_{\mathrm{max}} $$ ). The results indicated that during the second SDE cycle, the highest errors in θ $$ \theta $$ estimates were observed with the low power-short heat pulse, whereas the application of the low power-long duration and high power-short duration pulses improved the accuracy of calculations. Additionally, errors in θ $$ \theta $$ estimates escalated under wetter conditions, attributed to a shift in soil heat transfer capacity from the first to the second SDE cycle for θ $$ \theta $$ > 0.10 m3 m−3. This behaviour was ascribed to thermal hysteresis, arising from the contact resistance of the FOC and the alloy with the surrounding soil. Furthermore, the T max $$ {T}_{\mathrm{max}} $$ method exhibited the least sensitivity to this effect and yielded reliable θ $$ \theta $$ estimates, thus its adoption is recommended. Moreover, the use of the low power-long duration heating strategy is suggested as it promotes a trade-off between energy saving and accurate estimates. We concluded that assessing soil thermal response under multiple SDE cycles enhances the comprehension of the AHFO-DTS method. Overall, our findings provide insights into enhancing the applicability of this approach under field conditions, particularly following irrigation schedules and natural rainfall events.

加热光纤监测连续饱和-干燥循环下的土壤湿度:实验方法
近几十年来,分布式温度传感(DTS)已成为环境应用领域的一项强大技术,能够沿光纤电缆(FOC)进行高分辨率温度测量。主动加热光纤(AHFO)方法被用于监测土壤湿度(m3 m-3),通过 DTS 测量施加热脉冲后的土壤温度(AHFO-DTS 方法)。尽管 AHFO-DTS 在受控和自然条件下的应用有了很大改进,但对多次饱和-自然干燥循环过程中的土壤热行为却没有进行充分评估。本研究旨在填补这一空白,在实验室中构建了一个实验性水平土壤剖面,在两个连续的饱和-排水-蒸发(SDE)循环过程中应用 AHFO-DTS 方法。对与 FOC 接触的金属合金采用了三种加热策略,并使用校准模型与热导率()、累积温升()和最大温升()相关联。结果表明,在第二个 SDE 周期中,低功率-短时热脉冲的估计误差最大,而低功率-长持续时间脉冲和高功率-短持续时间脉冲的应用提高了计算的准确性。此外,在较潮湿的条件下,估算误差会增大,这归因于 0.10 立方米/立方米-3 的土壤传热能力从第一个 SDE 循环转移到第二个 SDE 循环。这种行为可归因于热滞后,这是由 FOC 和合金与周围土壤的接触电阻引起的。此外,该方法对这种效应的敏感性最低,并能得出可靠的估计值,因此建议采用。此外,我们还建议使用低功率、长持续时间的加热策略,因为这种方法可以在节能和精确估算之间进行权衡。我们的结论是,评估多个 SDE 循环下的土壤热响应可增强对 AHFO-DTS 方法的理解。总之,我们的研究结果为提高该方法在田间条件下的适用性提供了见解,尤其是在灌溉计划和自然降雨事件之后。
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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