A stabilized cut streamline diffusion finite element method for convection–diffusion problems on surfaces.

We develop a stabilized cut finite element method for the stationary convection–diffusion problem on a surface embedded in R d. The cut finite element method is based on using an embedding of the surface into a three dimensional mesh consisting of tetrahedra and then using the restriction of the standard piecewise linear continuous elements to a piecewise linear approximation of the surface. The stabilization consists of a standard streamline diffusion stabilization term on the discrete surface and a so called normal gradient stabilization term on the full tetrahedral elements in the active mesh. We prove optimal order a priori error estimates in the standard norm associated with the streamline diffusion method and bounds for the condition number of the resulting stiffness matrix. The condition number is of optimal order for a specific choice of method parameters. Numerical examples supporting our theoretical results are also included. • Stabilized cut finite element method for stationary convection–diffusion. • Streamline diffusion and surface normal gradient penalization. • Optimal order convergence irrespective of Péclet number. • Optimal condition number of the discrete system. [ABSTRACT FROM AUTHOR]