Title of article
Locally conservative, stabilized finite element methods for variably saturated flow Original Research Article
Author/Authors
C.E. Kees، نويسنده , , M.W. Farthing، نويسنده , , C.N. Dawson، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 2008
Pages
16
From page
4610
To page
4625
Abstract
Standard Galerkin finite element methods for variably saturated groundwater flow have several deficiencies. For instance, local oscillations can appear around sharp infiltration fronts without the use of mass-lumping, and velocity fields obtained from differentiation of pressure fields are discontinuous at element boundaries. Here, we consider conforming finite element discretizations based on a multiscale formulation along with recently developed, local postprocessing schemes. The resulting approach maintains the basic flexibility and appeal of traditional finite element methods, while controlling nonphysical oscillations and producing element-wise mass-conservative velocity fields. Accuracy and efficiency of the proposed schemes are evaluated through a series of steady-state and transient variably saturated groundwater flow problems in homogeneous as well as heterogeneous domains. The schemes are formulated for a generic nonlinear advection–diffusion equation and are thus applicable to many other flow models.
Keywords
Richards’ equation , Multiscale stabilization , Local conservation , Finite element method
Journal title
Computer Methods in Applied Mechanics and Engineering
Serial Year
2008
Journal title
Computer Methods in Applied Mechanics and Engineering
Record number
894427
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