High order ghost-FEM for incompressible Navier-Stokes equations on moving domains
This addresses computational fluid dynamics problems with moving boundaries, offering an efficient simulation tool for engineers and scientists, though it is incremental as it builds on existing ghost-FEM and boundary methods.
The paper tackled simulating incompressible fluid flow around moving objects by developing a high-order numerical method using ghost-FEM and IMEX schemes, achieving high-order accuracy and avoiding costly remeshing as validated through benchmark comparisons.
We develop a new numerical technique for approximating solutions of the Navier-Stokes equations on moving domains. The method aims at simulating an incompressible fluid past an object whose motion is assigned a priori using a level-set function. The proposed approach relies on a space discretization based on the ghost finite element method (ghost-FEM), which allows computations on unfitted meshes and avoids costly remeshing as the domain evolves in time. Time integration is performed using an IMplicit-EXplicit (IMEX) scheme to address the nonlinearity of the convective term, ensuring high-order accuracy for incompressible flows. The error introduced by the geometrical approximation is handled using the Shifted Boundary Method, which allows higher order approximations of boundary conditions on unfitted meshes. Dirichlet boundary conditions are imposed weakly by means of Nitsche's method. The associated stabilization parameter is chosen by solving a generalized eigenvalue problem, ensuring stability and accuracy of the numerical scheme. We present a series of numerical experiments designed to validate the accuracy of the proposed method, as well as comparisons with established benchmark problems involving moving boundaries.