Numerically quantifying the relative importance of topography and buoyancy in driving groundwater flow

Abstract: Both topography and buoyancy can drive groundwater flow; however, the interactions between them are still poorly understood. In this paper, the authors conduct numerical simulations of variable-density fluid flow and heat transport to quantify their relative importance. The finite element modeling experiments on a 2-D conceptual model reveal that the pattern of groundwater flow depends largely upon the relative magnitude of the flow rate due to topography alone and the flow rate due to buoyancy alone. When flu… Show more

“…This is particularly evident along western part of the system, where flow intensity has significantly increased due to the increased meteoric infiltration through the uncovered carbonates in the recent state of the system (Stage 4). In contrary, the effect of gravity is completely attenuated within the carbonate by the presence of an uppermost low-permeability layer along the eastern sub-system, beneath which fluid flow is clearly driven by thermal free convection, in agreement with the results of numerical experiments of Yang et al (2010). 9.…”

“…As the results have highlighted, the effect of gravity can be completely attenuated within the carbonate by the presence of an uppermost low-permeability layer, beneath which fluid flow is clearly controlled by thermally-driven free convection, in agreement with the results of the numerical experiments of Yang et al (2010). On the other hand, within the uncovered sub-system of Stage 4, the evolved slope of the water table is more important than buoyancy in controlling the fluid flow system, and upwelling is forced by the regional hydraulic gradient, analogous to acting in homogeneous unconfined aquifer, as described by Cserepes and Lenkey (2004).…”

Numerical Simulation of Groundwater Flow and Heat Transport Over Geological Time Scales at the Margin of Unconfined and Confined Carbonate Sequences

“…This is particularly evident along western part of the system, where flow intensity has significantly increased due to the increased meteoric infiltration through the uncovered carbonates in the recent state of the system (Stage 4). In contrary, the effect of gravity is completely attenuated within the carbonate by the presence of an uppermost low-permeability layer along the eastern sub-system, beneath which fluid flow is clearly driven by thermal free convection, in agreement with the results of numerical experiments of Yang et al (2010). 9.…”

“…As the results have highlighted, the effect of gravity can be completely attenuated within the carbonate by the presence of an uppermost low-permeability layer, beneath which fluid flow is clearly controlled by thermally-driven free convection, in agreement with the results of the numerical experiments of Yang et al (2010). On the other hand, within the uncovered sub-system of Stage 4, the evolved slope of the water table is more important than buoyancy in controlling the fluid flow system, and upwelling is forced by the regional hydraulic gradient, analogous to acting in homogeneous unconfined aquifer, as described by Cserepes and Lenkey (2004).…”

Numerical Simulation of Groundwater Flow and Heat Transport Over Geological Time Scales at the Margin of Unconfined and Confined Carbonate Sequences

“…Surface topography, heterogeneities in the rock and/or perturbations inducing transient conditions may cause a combination of these processes to occur to varying extents, at different times or in different parts of the same system. For instance, in mountainous terrain mixed flow systems may evolve when topography‐driven flow is imposed on free convection (e.g., Cserepes & Lenkey, 2004; Raffensperger & Vlassopoulos, 1999; Szijárto et al., 2019; Yang et al., 2010). Thus, a given flow pattern, if not controlled by the permeability distribution (i.e., assuming homogeneous conditions), reflects the balance of forces driving these different modes of flow.…”

Effect of Glacial/Interglacial Recharge Conditions on Flow of Meteoric Water Through Deep Orogenic Faults: Insights Into the Geothermal System at Grimsel Pass, Switzerland

“…Geological and Hydrogeological Setting. The Qaidam Basin is a large closed intermountain fault basin in which the maximum thickness of the Quaternary sediments exceeds 3000 m [11]. From the piedmont to the central basin, the structural characteristics of the water-bearing media generally have zonal or semizonal distributions.…”

“…Tóth summarized two major classes of controlling factors: the geometric morphology of the basin and the geological conditions of the basin [7]. In addition, many scholars believe that the upper boundary conditions and the physical properties of the fluid are also important factors that affect the movement of groundwater in a basin [8][9][10][11]. Li and Hao [12] adopted a multidisciplinary research method to determine that inland basins can be roughly divided into four grades of flow systems and three characteristic zones of salt migration, and they explained the formation mechanism for the freshwater segment of an inland basin.…”

Numerical Investigation into the Evolution of Groundwater Flow and Solute Transport in the Eastern Qaidam Basin since the Last Glacial Period