Accurate numerical methods for two and three dimensional integral fractional Laplacian with applications

Abstract

In this paper, we propose accurate and efficient finite difference methods to discretize the two- and three-dimensional fractional Laplacian (-)α2 (0 < α < 2) in hypersingular integral form. The proposed finite difference methods provide a fractional analogue of the central difference schemes to the fractional Laplacian, and as α 2-, they collapse to the central difference schemes of the classical Laplace operator -. We prove that our methods are consistent if u ∈ Cα, α-α+ε( Rd), and the local truncation error is O(hε), with ε > 0 a small constant and · denoting the floor function. If u ∈ C2+α, α-α+ε( Rd), they can achieve the second order of accuracy for any α ∈ (0, 2). These results hold for any dimension d 1 and thus improve the existing error estimates for the finite difference method of the one-dimensional fractional Laplacian. Extensive numerical experiments are provided and confirm our analytical results. We then apply our method to solve the fractional Poisson problems and the fractional Allen-Cahn equations. Numerical simulations suggest that to achieve the second order of accuracy, the solution of the fractional Poisson problem should at most satisfy u ∈ C1,1( Rd). One merit of our methods is that they yield a multilevel Toeplitz stiffness matrix, an appealing property for the development of fast algorithms via the fast Fourier transform (FFT). Our studies of the two- and three-dimensional fractional Allen-Cahn equations demonstrate the efficiency of our methods in solving the high-dimensional fractional problems.