Spatiotemporal monitoring of water storage in the North China Plain from 2002 to 2022 based on an improved GRACE downscaling method

IF 4.7 2区地球科学 Q1 WATER RESOURCES

Journal of Hydrology-Regional Studies Pub Date : 2025-04-08 DOI:10.1016/j.ejrh.2025.102370

Jinze Tian , Yu Chen , Shuai Wang , Xinlong Chen , Huibin Cheng , Xiaolong Tian , Xue Wang , Kun Tan

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引用次数: 0

Abstract

Study region

North China Plain (NCP), a major agricultural region in China.

Study focus

The coupling effects of key drivers on water storage dynamics were quantitatively analyzed, integrating frequency-domain correlation analysis to identify lag effects, which were incorporated into a Random Forest (RF) downscaling method. GRACE data were refined through this approach, enhancing spatial resolution while maintaining accuracy, with the aim of precisely characterizing water storage dynamics and examining its interactions with climatic and anthropogenic factors, particularly the long-term impact of groundwater fluctuations on surface deformation.

New hydrological insight for the region

Terrestrial Water Storage Anomaly (TWSA), Shallow Water Storage Anomaly (SWSA), and Groundwater Storage Anomaly (GWSA) were derived for the NCP over the past two decades at a 0.25° resolution. The enhanced downscaling model demonstrated improved performance, with a higher Nash-Sutcliffe efficiency (+0.05), an increased correlation coefficient (+0.03), and a reduced root-mean-square error (-0.32 cm). From 2014–2022, interannual water storage fluctuations intensified, with divergent trends for TWSA (0.30 cm/year), SWSA (1.47 cm/year), and GWSA (-0.97 cm/year). Major influencing factors include water diversion projects, increased precipitation, and reduced societal water consumption. Surface deformation lags behind GWSA by 5–6 months, with a long-term lag of 10 months and a correlation of 0.81. These findings deepen the understanding of water storage dynamics and their impact on surface deformation in the NCP.

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基于改进GRACE降尺度方法的2002 - 2022年华北平原储水量时空监测

研究区域华北平原是中国主要的农业区。研究重点定量分析了关键驱动因素对储水动态的耦合效应，结合频域相关分析识别滞后效应，并将滞后效应纳入随机森林降尺度方法。通过这种方法对GRACE数据进行了细化，在保持精度的同时提高了空间分辨率，目的是精确表征储水动态并研究其与气候和人为因素的相互作用，特别是地下水波动对地表变形的长期影响。在0.25°分辨率下，获得了近20年来NCP区域陆地蓄水异常（TWSA）、浅水蓄水异常（SWSA）和地下水蓄水异常（GWSA）的新水文信息。增强的降尺度模型表现出更高的性能，具有更高的Nash-Sutcliffe效率（+0.05），增加的相关系数（+0.03）和降低的均方根误差（-0.32 cm）。2014-2022年，年际蓄水量波动加剧，TWSA（0.30 cm/年）、SWSA（1.47 cm/年）和GWSA（-0.97 cm/年）的变化趋势存在差异。主要影响因素包括引水工程、降水增加和社会用水量减少。地表变形滞后于GWSA 5 ~ 6个月，长期滞后10个月，相关性为0.81。这些发现加深了对北太平洋流域水储存动力学及其对地表变形影响的理解。

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

Journal of Hydrology-Regional Studies Earth and Planetary Sciences-Earth and Planetary Sciences (miscellaneous)

CiteScore

6.70

自引率

8.50%

发文量

284

审稿时长

60 days

期刊介绍： Journal of Hydrology: Regional Studies publishes original research papers enhancing the science of hydrology and aiming at region-specific problems, past and future conditions, analysis, review and solutions. The journal particularly welcomes research papers that deliver new insights into region-specific hydrological processes and responses to changing conditions, as well as contributions that incorporate interdisciplinarity and translational science.