Evaluation of drought impact on groundwater recharge rate using SWAT and Hydrus models on an agricultural island in western Japan

Clarifying the variations of groundwater recharge response to a changing non-stationary hydrological process is important for efficiently managing groundwater resources, particularly in regions with limited precipitation that face the risk of water shortage. However, the rate of aquifer recharge is...

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Bibliographic Details
Published in:Proceedings of the International Association of Hydrological Sciences 2015-01, Vol.371 (371), p.143-148
Main Authors: Jin, G, Shimizu, Y, Onodera, S, Saito, M, Matsumori, K
Format: Article
Language:English
Subjects:
Agricultural management
Annual precipitation
Annual variations
Aquifer recharge
Aquifers
Atmospheric precipitations
Calibration
Climate change
Climatic conditions
Computer simulation
Drought
Droughts
Environmental aspects
Environmental impact
Evapotranspiration
Flood frequency
Groundwater
Groundwater levels
Groundwater recharge
Groundwater resources
Groundwater runoff
Hydrologic processes
Hydrology
Japan
Precipitation
Precipitation variations
Rain
Rainfall
Rainfall intensity
Recharge areas
Runoff
Simulation
Soils
Spatial variations
Surface runoff
Surface water
Temporal variations
Topography
Water discharge
Water resources
Water shortages
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Summary:Clarifying the variations of groundwater recharge response to a changing non-stationary hydrological process is important for efficiently managing groundwater resources, particularly in regions with limited precipitation that face the risk of water shortage. However, the rate of aquifer recharge is difficult to evaluate in terms of large annual-variations and frequency of flood events. In our research, we attempt to simulate related groundwater recharge processes under variable climate conditions using the SWAT Model, and validate the groundwater recharge using the Hydrus Model. The results show that annual average groundwater recharge comprised approximately 33% of total precipitation, however, larger variation was found for groundwater recharge and surface runoff compared to evapotranspiration, which fluctuated with annual precipitation variations. The annual variation of groundwater resources is shown to be related to precipitation. In spatial variations, the upstream is the main surface water discharge area; the middle and downstream areas are the main groundwater recharge areas. Validation by the Hydrus Model shows that the estimated and simulated groundwater levels are consistent in our research area. The groundwater level shows a quick response to the groundwater recharge rate. The rainfall intensity had a great impact on the changes of the groundwater level. Consequently, it was estimated that large spatial and temporal variation of the groundwater recharge rate would be affected by precipitation uncertainty in future.
ISSN:2199-899X
0144-7815
2199-8981
2199-899X
DOI:10.5194/piahs-371-143-2015