Assessing the use of standardized groundwater index for quantifying groundwater drought over the conterminous US

•The lognormal function was the best-fitting function to calculate SGI based on the monitoring data from the 100 wells located in US.•There existed a significant difference of changes in SGI over different areas.•The SGI had a similar temporal pattern in different seasons from 1981 to 2010 in the sa...

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Bibliographic Details
Published in:Journal of hydrology (Amsterdam) 2021-07, Vol.598, p.126227, Article 126227
Main Authors: Guo, Mengshen, Yue, Weifeng, Wang, Tiejun, Zheng, Nengzhan, Wu, Lijun
Format: Article
Language:English
Subjects:
Groundwater drought
Lag effect
SGI
SPI
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Summary:•The lognormal function was the best-fitting function to calculate SGI based on the monitoring data from the 100 wells located in US.•There existed a significant difference of changes in SGI over different areas.•The SGI had a similar temporal pattern in different seasons from 1981 to 2010 in the same region.•The lag effect between SGI and SPI was obvious and the cross-correlation coefficients increased with the increasing time scales. Groundwater drought is a drought phenomenon caused by the decrease in groundwater level or groundwater storage under natural and anthropogenic disturbances (e.g., climate variability/change and groundwater abstraction). Due to the complexity of groundwater flow systems and the difficulty in obtaining direct observational data related to groundwater resources, it remains challenging to characterize groundwater drought quantitatively. To this end, standardized groundwater level index (SGI), which was modified from the standardized precipitation index (SPI), was used to quantify groundwater drought with the long-term groundwater level data (1981–2010) obtained from the Climate Response Network wells across the conterminous United States. The best fitting function of groundwater level distributions was lognormal which was selected from various distribution functions based on the Anderson-Darling (AD) test among 100 wells. Four monitoring wells located in Georgia, Massachusetts, Oklahoma and Washington were selected as the main research objects. The trend of change in groundwater level was divided into two categories: the wells in Georgia and Oklahoma showed an initial decrease followed by an increase while the wells in Massachusetts and Washington showed a continuous decline. Groundwater drought varied significantly in different areas due to the complexity of geographical location, agricultural irrigation, population and other natural environment and human activities. Start and end time of drought conditions and the severity of drought and flooding at different time scales in the same area also varied, therefore it is necessary to describe different groundwater droughts at a reasonable time scale. In this paper, the difference between SGI and SPI at different time scales was so obvious that the cross-correlation analysis was used to find the law of lag time. The cross-correlation coefficients increased with the increasing time scales, and the average correlation values between SPI and SGI of wells in Georgia, Massachusetts, Okla
ISSN:0022-1694
1879-2707
DOI:10.1016/j.jhydrol.2021.126227