Scalable ADER-DG Transport Method with Polynomial Order Independent CFL Limit

Discontinuous Galerkin (DG) methods are known to suffer from increasingly restrictive time step constraints as the polynomial order increases, limiting their efficiency at high orders. In this paper, we introduce a novel locally implicit, but globally explicit ADER-DG scheme designed for transport-dominated problems. The method achieves a maximum stable time step governed by an element-width based CFL condition that is independent of the polynomial degree. By solving a set of element-local implicit problems at each time step, our approach more effectively captures the domain of dependence. As a result, our method remains stable for CFL numbers up to $1/\sqrt{d}$ in $d$ spatial dimensions. We provide a rigorous stability proof in one dimension, and extend the analysis to two and three dimensions using a semi-analytical von Neumann stability analysis. The accuracy and convergence of the method are demonstrated through numerical experiments on both linear and nonlinear test cases.