Solving 3D Subsurface Flow and Transport with Adaptive Multigrid

This paper presents an adaptive multigrid approach, combining multigrid methods and adaptive local grid refinement, to solve 3D density-dependent flow and transport problems in the subsurface. This approach is incorporated with the Galerkin finiteelement method to solve the modified Richardsʹ equation in the flow module and the Lagrangian-Eulerian finite-element method to solve the advection-dispersion equation in the transport module, which are coupled through density effects. With multigrid methods, the linear/linearized matrix equations can be solved with O(n) manipulations to save computer time. With adaptive local grid refinement, computational accuracy is improved by refining only rough regions of the problem domain and the computation is efficiently achieved because computer efforts are focused on those regions. In this work, rough regions are determined by examining the mesh Péclet number during each nonlinear iteration of the flow module and by checking the smoothness of the Lagrangian concentrations over global elements in the Lagrangian step of the transport module. Based on the detected rough regions, a modular setting of grid generation is employed to generate local zooming grids as well as to prepare the information needed for applying multigrid methods. Two examples are given to demonstrate the success of this approach.