Heat and moisture transport characteristics in permafrost embankment under seasonal rainfall

IF 2 3区地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY

Frontiers in Earth Science Pub Date : 2024-08-30 DOI:10.3389/feart.2024.1442576

Zhanxu Wang, Laifa Wang, Xinyan Wang, Feng Ming

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Abstract

The Tibetan Plateau has exhibited a discernible trend towards increased precipitation over the past 50 years. However, previous research predominantly focused on thermal stability of permafrost without the consideration of water flux boundary conditions, and therefore ignored the dynamics of water migration and its impacts on the embankment stability. To bridge this gap, a novel water-heat transfer model incorporating rainfall and water migration was developed and subsequently validated using monitored data. Comparative analyses were then conducted across three distinct rainfall intensities to investigate the variations in the moisture and temperature of superficial soil. Results indicate rainfall events exert a notable cooling effect during warm seasons but have little influence on cooling during cold seasons. By increasing the latent heat of evaporation, sensible heat and reducing the soil heat flux, rainfall results in embankment cooling, and the cooling effect correlates positively with rainfall intensity. Disregarding the water flux boundary conditions will overestimate the embankment temperature and underestimate the variation of water content, especially at the superficial soil. Rainfall results in a decline in water vapor flux and an increase in liquid water flux, which facilitates rapid downward transport and accumulation of liquid water. Despite the increased convective heat transfer of liquid water, the decrease in heat conduction, latent heat of evaporation and convective heat transfer of water vapor in the embankment is more pronounced. Rainfall changes the stability of permafrost embankment mainly by adjusting the energy distribution, which delays temperature increases in the underlying permafrost. When predicting the stability of permafrost, it is recommended to incorporate the water flux boundary conditions.

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季节性降雨条件下冻土路堤的热量和水分传输特性

青藏高原在过去 50 年中呈现出降水量明显增加的趋势。然而，以往的研究主要集中于冻土的热稳定性，而没有考虑水流的边界条件，因此忽略了水迁移的动态及其对路堤稳定性的影响。为了弥补这一缺陷，我们开发了一种包含降雨和水迁移的新型水热传导模型，并随后利用监测数据进行了验证。然后对三种不同的降雨强度进行了对比分析，以研究表层土壤的水分和温度变化。结果表明，降雨事件在温暖季节会产生明显的降温效果，但在寒冷季节对降温影响不大。降雨增加了蒸发潜热、显热，减少了土壤热通量，从而导致堤坝降温，降温效果与降雨强度呈正相关。忽略水通量边界条件会高估路堤温度，低估含水量的变化，尤其是表层土壤。降雨导致水蒸气通量下降，液态水通量增加，这有利于液态水的快速向下输送和积聚。尽管液态水的对流换热量增加，但堤坝中的热传导、蒸发潜热和水蒸气的对流换热量的减少更为明显。降雨主要通过调整能量分布来改变冻土路堤的稳定性，从而延缓下层冻土的温度上升。在预测冻土稳定性时，建议结合水通量边界条件。

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

Frontiers in Earth Science Earth and Planetary Sciences-General Earth and Planetary Sciences

CiteScore

3.50

自引率

10.30%

发文量

2076

审稿时长

12 weeks

期刊介绍： Frontiers in Earth Science is an open-access journal that aims to bring together and publish on a single platform the best research dedicated to our planet. This platform hosts the rapidly growing and continuously expanding domains in Earth Science, involving the lithosphere (including the geosciences spectrum), the hydrosphere (including marine geosciences and hydrology, complementing the existing Frontiers journal on Marine Science) and the atmosphere (including meteorology and climatology). As such, Frontiers in Earth Science focuses on the countless processes operating within and among the major spheres constituting our planet. In turn, the understanding of these processes provides the theoretical background to better use the available resources and to face the major environmental challenges (including earthquakes, tsunamis, eruptions, floods, landslides, climate changes, extreme meteorological events): this is where interdependent processes meet, requiring a holistic view to better live on and with our planet. The journal welcomes outstanding contributions in any domain of Earth Science. The open-access model developed by Frontiers offers a fast, efficient, timely and dynamic alternative to traditional publication formats. The journal has 20 specialty sections at the first tier, each acting as an independent journal with a full editorial board. The traditional peer-review process is adapted to guarantee fairness and efficiency using a thorough paperless process, with real-time author-reviewer-editor interactions, collaborative reviewer mandates to maximize quality, and reviewer disclosure after article acceptance. While maintaining a rigorous peer-review, this system allows for a process whereby accepted articles are published online on average 90 days after submission. General Commentary articles as well as Book Reviews in Frontiers in Earth Science are only accepted upon invitation.