Abstract
Significant variation in the precipitation events caused by global climate change has made it difficult to manage water resources due to the increased frequency of unexpected droughts and floods. Under these conditions, groundwater is needed to ensure a sustainable water supply; thus, estimates of precipitation recharge are essential. In this study, we derived an apparent recharge coefficient (ARC) from a modified water table fluctuation equation to predict groundwater storage changes due to precipitation events. The ARC is calculated as the ratio of the recharge rate over the specific yield (R/Sy); therefore, it implicitly expresses variation in Sy. The ARC varies spatially and temporally, corresponding to the precipitation events and hydrogeological characteristics of unsaturated materials. ARCs for five monitoring wells from two basins in Korea in different seasons were calculated using a 10-year groundwater level and weather dataset for 2005–2014. Then, the reliability of the ARCs was tested by the comparison of the predicted groundwater level changes for 2015 and 2016 with observed data. The root mean square error ranged from 0.03 to 0.09 m, indicating that the predictions were acceptable, except for one well, which had thick clay layers atop the soil layer; the low permeability of the clay slowed the precipitation recharge, interfering with groundwater level responses. We performed a back-calculation of R from the Sy values of the study areas; the results were similar to those obtained via other methods, confirming the practical applicability of the ARC. In conclusion, the ARC is a viable method for predicting groundwater storage changes for regions where long-term monitoring data are available, and subsequently will facilitate advanced decision making for allocating and developing water resources for residents, industry, and groundwater-dependent ecosystems.
Highlights
The Intergovernmental Panel on Climate Change (IPCC) has reported variability in precipitation trends in Asia due to global climate change [1]
We developed a metric for the short-term prediction of groundwater level increase and the estimation of groundwater recharge following precipitation events: the apparent recharge coefficient (ARC)
We developed a simple and direct method to assess groundwater recharge, using the relationship between precipitation events and the corresponding groundwater level rises
Summary
The Intergovernmental Panel on Climate Change (IPCC) has reported variability in precipitation trends in Asia due to global climate change [1]. The time scale of recharge varies depending on the characteristics of the precipitation events (e.g., amount, duration, and frequency) and the geologic materials within the unsaturated zone. Groundwater may take from hours to decades to exhibit the influence of precipitation events, depending on site-specific hydrogeological characteristics. This extended response of groundwater systems to precipitation is the principal mechanism that sustains water supply for human societies, even during dry periods. For this reason, it is important to understand and monitor groundwater recharge processes [6,7,8,9]
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