Beyond Free-Stream Preservation: Transport Polynomial Exactness for Moving-Mesh Methods under Arbitrary Mesh Motion

Abstract

High-order moving-mesh methods can effectively reduce numerical diffusion, but their formal accuracy typically relies on the regularity of the mesh velocity. This dependency creates a fundamental conflict in the numerical solution of hyperbolic conservation laws, where solution-driven adaptation may induce nonsmooth mesh motion, thereby degrading convergence order. We introduce transport polynomial exactness (TPE(k)), a mesh-motion-independent criterion that generalizes classical free-stream preservation (TPE(0)) to the exact advection of degree-k polynomials. We show that the classical geometric conservation law (GCL) is insufficient to ensure TPE(k) for k 1 due to mismatches in higher-order geometric moments. To resolve this, we propose evolved geometric moments (EGMs), obtained by solving auxiliary transport equations discretized compatibly with the physical variables. We rigorously prove that second-degree EGMs evolved via the third-order strong stability preserving Runge--Kutta (SSPRK3) method coincide with the exact geometric moments. This exactness arises from a superconvergence mechanism wherein SSPRK3 reduces to Simpson's rule for EGM evolution. Leveraging this result, we construct a third-order conservative finite-volume rezoning moving-mesh scheme. The scheme satisfies the TPE(2) property for arbitrary mesh motion and any pseudo-time step size, thereby naturally accommodating spatiotemporally discontinuous mesh velocity. Crucially, this breaks the efficiency bottleneck in the conventional advection-based remapping step and reduces the required pseudo-time levels from O(h-1) to O(1) under bounded but discontinuous mesh velocity. Numerical experiments verify exact quadratic transport and stable third-order convergence under extreme mesh deformation, demonstrating substantial efficiency gains.