New understanding of topography-driven groundwater flow through a fully-coupled framework published with Journal of Hydrology

Editors:谢月清Release time:2021-01-21Clicks:52


Conceptual model for simulating topography-driven groundwater flow with a surface-water and groundwater coupled modeling framework.

Numerical models with spatially-varying head as top boundary conditions were used in previous studies to understand topography-driven groundwater flow. The head boundary conditions could cause artifacts of extremely large, but unrealistic recharge rates owing to unlimited  supply of water. This study adopted a fully-coupled surface–subsurface hydrologic modeling approach to simulate transient topography-driven groundwater flow and also surface-water flow under homogeneous and  isotropic settings. Two 100-year climate datasets and five hydraulic conductivities (K, 0.01–100 m/d) were tested in numerical experiments. In the base case with a wet climate (annual precipitation 1696 mm/y) and K of 1 m/d, groundwater head at two different locations close to both  lateral boundaries fluctuates only within 5.1 m and 9.6 m, respectively, during the 100-year period. Despite the local water table fluctuations caused by the variability in the climatic record, large-scale groundwater flow systems can be assumed in dynamic equilibrium provided  stationary climate. Long-term average exchange fluxes are spatially constant and limited by precipitation infiltration when surface water is absent, whereas they vary from positive to negative values (i.e., recharge to discharge) spatially when surface water is present.  Sensitivity analysis suggests that wetter climate and smaller K lead to more inundation of the land surface, stronger hierarchical nesting of groundwater flow systems and more variable exchange fluxes.  Overall, our first fully-coupled modeling of topography-driven groundwater flow implies that attention must be paid to causality  between head and flow, and climatic record as boundary conditions may be  more appropriate due to its relaxed manner.

Please click on the following link to access our paper: https://www.sciencedirect.com/science/article/pii/S0022169420314116