$L^{\infty}$-error estimate for the finite element method on two dimensional surfaces
Provides a theoretical error bound for surface finite element methods, but the result is incremental as it extends known Euclidean estimates to surfaces.
The paper establishes an $L^{\\infty}$-error estimate of order $O(h^2|\\log h|)$ for finite element approximations of Laplace-Beltrami equations on two-dimensional surfaces, matching the Euclidean case.
We approximate the solution of the equation $$ -Δ_S u+u = f $$ on a two-dimensional, embedded, orientable, closed surface $S$ where $-Δ_S$ denotes the Laplace Beltrami operator on $S$ by using continuous, piecewise linear finite elements on a triangulation of $S$ with flat triangles. We show that the $L^{\infty}$-error is of order $O(h^2|\log h|)$ as in the corresponding situation in an Euclidean setting.