Annual Trends of Soil Moisture and Rainfall Flux in an Arid Climate Using Remote Sensing Data

Highlights of Sustainability Pub Date : 2022-08-18 DOI:10.54175/hsustain1030013

M. Valipour, Helaleh Khoshkam, S. Bateni, E. Heggy

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引用次数: 2

Abstract

The water crisis is still a major issue in Qatar. Seawater desalination has been strongly implemented in the Persian Gulf region. However, it is costly and there is corrosion in piping materials and other equipment. Hence, there is a vital need to detect groundwater resources in Qatar. Various factors affect the variability of groundwater in Qatar including hydrogeological aspects, climate change, drawdown and abstraction, rainwater harvesting, desertification, and population growth. In this study, we employ the Famine Early Warning Systems Network (FEWS NET) Land Data Assimilation System (FLDAS) to monitor annual variations of soil moisture (SM) in the depth of 1–2 m (as an indicator of groundwater) and rainfall flux (RF) from 1982 to 2019. The results show that SM and RF anomalies were positive from 1982 to 2000 (except 1992). In contrast, these anomalies became negative during 2001–2019 (expect 2001 and 2018), implying the drawdown of groundwater resources. Drier years (i.e., negative RF anomaly) in the recent 19 years (2001–2019) reduced SM and led to a negative SM anomaly. The Mukaynis and Wadi Jallal regions (located in Al Rayyan and Al Wakrah municipalities, respectively) had the highest RF and SM from 1982 to 2019. The center-pivot irrigation systems close to the Mukaynis and Wadi Jallal regions indicate their accessibility to groundwater resources in Qatar. Moreover, these regions have the lowest risk of salinization and groundwater vulnerability. In addition, annual trends of groundwater storage (GWS) retrieved from the Gravity Recovery and Climate Experiment (GRACE) from 2003 to 2019 have been presented. This study is beneficial for detecting and monitoring groundwater resources for the sustainable management of water resources in arid environments.

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基于遥感数据的干旱气候下土壤水分和降雨通量的年变化趋势

水危机仍然是卡塔尔的一个主要问题。海水淡化在波斯湾地区得到大力实施。然而，它是昂贵的，并且在管道材料和其他设备中存在腐蚀。因此，非常需要探测卡塔尔的地下水资源。影响卡塔尔地下水变化的因素多种多样，包括水文地质方面、气候变化、降水和抽取、雨水收集、荒漠化和人口增长。本研究利用饥荒预警系统网络(FEWS NET)土地数据同化系统(FLDAS)监测1982 - 2019年1 ~ 2 m深度土壤水分(SM)(作为地下水指标)和降雨通量(RF)的年变化。结果表明:1982 ~ 2000年(1992年除外)，SM和RF均为正异常。相比之下，这些异常在2001 - 2019年期间变为负值(预计2001年和2018年)，这意味着地下水资源的减少。近19年(2001-2019)的干旱年份(即负RF异常)减少了SM，导致了负SM异常。Mukaynis和Wadi Jallal地区(分别位于Al Rayyan和Al Wakrah市)在1982年至2019年期间的RF和SM最高。靠近Mukaynis和Wadi Jallal地区的中心支点灌溉系统表明卡塔尔地下水资源的可及性。此外，这些地区盐渍化和地下水脆弱性的风险最低。此外，还介绍了2003 - 2019年重力恢复与气候试验(GRACE)反演的地下水储量(GWS)的年变化趋势。该研究有助于干旱环境下地下水资源的探测和监测，为水资源的可持续管理提供依据。

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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Highlights of Sustainability

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