Sharp and unified L2 error estimates for the nonsymmetric Nitsche method on convex polytopes

Abstract

Nitsche's method weakly imposes Dirichlet boundary conditions, but its nonsymmetric variant has long shown a gap between theory and computation: the classical L2~analysis under Hk+1~regularity predicts a half-order convergence loss, whereas numerical experiments on smooth test problems consistently produce the optimal rate. Whether this discrepancy reflects a limitation of the analysis or an essential feature of the method has remained an open question. On bounded convex polytopes in two and three dimensions, we prove a unified, regularity-dependent L2~error estimate valid across the entire penalty scale h-α: align* \|u-uh\|L2(Ω) C hr |u|Wk+1,p(Ω), r=\k+1,\,k+\1,α\-1/p\. align* Numerical experiments in two and three dimensions, on a one-parameter family of manufactured solutions with tunable regularity, demonstrate the sharpness of the estimate and resolve the open question. First, under merely Hk+1~regularity the half-order loss is essential; second, the optimal convergence consistently observed on smooth test problems is therefore explained by their full Wk+1,∞~regularity, not by a limitation of the standard analysis. The theory identifies α 1+1/p or p=∞ as the sharp threshold for recovering the optimal rate hk+1, and the experiments confirm this if-and-only-if condition in both dimensions.