Global superconvergence of the lowest order mixed finite element on mildly structured meshes
Provides theoretical superconvergence results for mixed finite elements on meshes with approximate parallelogram property, benefiting numerical analysts working on elliptic problems.
The paper proves global superconvergence of order 1+ρ (ρ∈(0,1]) for the lowest order Raviart-Thomas mixed finite element method on mildly structured triangular meshes, and achieves the same order for the postprocessed solution via a local operator.
In this paper, we develop global superconvergence estimates for the lowest order Raviart--Thomas mixed finite element method for second order elliptic equations with general boundary conditions on triangular meshes, where most pairs of adjacent triangles form approximate parallelograms. In particular, we prove the $L^{2}$-distance between the numerical solution and canonical interpolant for the vector variable is of order $1+ρ$, where $ρ\in(0,1]$ is dependent on the mesh structure. By a cheap local postprocessing operator $G_{h}$, we prove the $L^{2}$-distance between the exact solution and the postprocessed numerical solution for the vector variable is of order $1+ρ$. As a byproduct, we also obtain the superconvergence estimate for Crouzeix--Raviart nonconforming finite elements on triangular meshes of the same type.