Simulating the Predevelopment Groundwater-Surface Water Flow System in the San Joaquin Valley, California
Simulating the Predevelopment Groundwater-Surface Water Flow System in the San Joaquin Valley, California
Presented on Monday, May 5, 2014
The San Joaquin Valley (SJV) in central California has significant water management concerns, given the high water demand for an increasing state population and for intense irrigation. The groundwater-surface water system in the area has undergone drastic changes since the employment of groundwater and surface water extractions for irrigation and mining, and is still responding to past and present stresses. The physically-based surface-subsurface numerical HydroGeoSphere model is used to examine the regional-scale hydrologic budget of the SJV at predevelopment conditions, constrained by available historical data. This study is distinguished from previous investigations by covering more of the SJV, incorporating a true predevelopment condition, and using a physically-based surface-subsurface hydrologic model. As a result, complex hydrologic processes, including groundwater-surface water interaction along the major rivers and within wetland areas formed by flooded surface water, as well as evapotranspiration (ET) and impacted root zone processes, were identified in the area. The presence and path of the major rivers in the domain are well defined in the model output. The general location and formation of the major wetlands simulated by the model, and the hydrologic processes that occurred within them, have a fair agreement with historical records. There is also a fair match between simulated and estimated water table elevations. ET is a significant sink of both surface water and groundwater. Successful simulation of the hydrologic processes and features, and the water balance of the natural system, underscores the importance of using an integrated model to analyze watershed-scale systems. This predevelopment hydrologic condition could serve as a reasonable initial state for future transient runs that bring the model up to current hydrologic conditions in order to estimate present and future water budgets.