An Embedded Boundary Scheme for Three-Dimensional Flow Over Terrain on a Staggered Mesh
This work addresses the challenge of simulating flow over complex terrain in atmospheric models, providing a more flexible alternative to terrain-following coordinates.
This paper presents an embedded boundary (EB) method for three-dimensional flow over terrain on a staggered mesh, extending the weighted state redistribution scheme to handle small-cell instabilities. The method is validated by comparing simulations with terrain-following coordinates, showing good agreement.
This paper describes an embedded boundary (EB) approach for simulating three-dimensional fluid flow on a staggered mesh where the velocity components are defined on cell faces and the thermodynamic state is defined on cell centers. Most EB approaches assume that all components of the solution, including the velocity, are co-located. To compute solution quantities on faces as well as cell centers, we construct and store multiple instances of the geometric information, one for the quantities stored at cell centers and one for each velocity component. In addition, we extend the weighted state redistribution (WSRD) scheme to staggered meshes to address the small-cell instability issue. This new approach is implemented in the Energy Research and Forecasting (ERF) model that provides performance portability and adaptive mesh refinement. We validate the new EB method by comparing EB simulations to those computed using terrain-following coordinates.