Tensor FEM for spectral fractional diffusion

Abstract

We design and analyze several Finite Element Methods (FEMs) applied to the Caffarelli-Silvestre extension that localizes the fractional powers of symmetric, coercive, linear elliptic operators in bounded domains with Dirichlet boundary conditions. We consider open, bounded, polytopal but not necessarily convex domains Ω⊂ Rd with d=1,2. For the solution to the extension problem, we establish analytic regularity with respect to the extended variable y∈ (0,∞). We prove that the solution belongs to countably normed, power-exponentially weighted Bochner spaces of analytic functions with respect to y, taking values in corner-weighted Kondat'ev type Sobolev spaces in Ω. In Ω⊂ Rd, we discretize with continuous, piecewise linear, Lagrangian FEM (P1-FEM) with mesh refinement near corners, and prove that first order convergence rate is attained for compatible data f∈ H1-s(Ω). We also prove that tensorization of a P1-FEM in Ω with a suitable hp-FEM in the extended variable achieves log-linear complexity with respect to NΩ, the number of degrees of freedom in the domain Ω. In addition, we propose a novel, sparse tensor product FEM based on a multilevel P1-FEM in Ω and on a P1-FEM on radical-geometric meshes in the extended variable. We prove that this approach also achieves log-linear complexity with respect to NΩ. Finally, under the stronger assumption that the data is analytic in Ω, and without compatibility at ∂ Ω, we establish exponential rates of convergence of hp-FEM for spectral, fractional diffusion operators. We also report numerical experiments for model problems which confirm the theoretical results. We indicate several extensions and generalizations of the proposed methods.