A hybridizable discontinuous Galerkin method for fractional diffusion problems

Abstract

We study the use of the hybridizable discontinuous Galerkin (HDG) method for numerically solving fractional diffusion equations of order -α with -1<α<0. For exact time-marching, we derive optimal algebraic error estimates assuming that the exact solution is sufficiently regular. Thus, if for each time t ∈ [0,T] the approximations are taken to be piecewise polynomials of degree k0 on the spatial domain~Ω, the approximations to u in the L∞(0,T;L2(Ω))-norm and to ∇ u in the L∞(0,T; L2(Ω))-norm are proven to converge with the rate hk+1, where h is the maximum diameter of the elements of the mesh. Moreover, for k1 and quasi-uniform meshes, we obtain a superconvergence result which allows us to compute, in an elementwise manner, a new approximation for u converging with a rate of (T h-2/(α+1))\, \,hk+2.