Stabilization and Operator Preconditioning of Bulk--Surface CutFEM via Harmonic Extension

Abstract

We present a cut finite element method (CutFEM) for the Laplace--Beltrami equation on a smooth closed curve ⊂R2 coupled to a harmonic bulk problem in that requires no explicit stabilization: no ghost penalty, normal-gradient penalty, or cell agglomeration. The classical ill-conditioning of trace finite element spaces on cut cells arises from basis functions with vanishingly small support on ; our observation is that coupling the surface discretization to a discrete bulk harmonic extension, realized through the lattice Green's function (LGF) on the background Cartesian grid, rigidly constrains the degrees of freedom responsible for this ill-conditioning. The reduced operator, obtained by a congruence transform of the full CutFEM stiffness, inherits symmetry and positive semi-definiteness from the variational form and has a condition number bounded uniformly in the smallest cut-cell ratio. The direct reconstruction has the standard O(h-2) mesh conditioning; the single-layer density formulation acts as operator preconditioner and yields O(1) conditioning, which is amenable to iterative solvers; the double-layer density formulation remains cut-independent with O(h-2) scaling. We prove optimal O(h)/O(h2) error estimates in H1()/L2() under standard regularity assumptions, establish the cut-independent conditioning rigorously, and demonstrate both the optimal convergence rate and robustness with respect to small cuts in numerical experiments.