On Fundamental Solutions of Higher-Order Space-Fractional Dirac equations

Abstract

Starting from the pseudo-differential decomposition D=(-)12H of the Dirac operator D=Σj=1nej∂xj in terms of the fractional operator (-)12 of order 1 and of the Riesz-Hilbert type operator H we will investigate the fundamental solutions of the space-fractional Dirac equation of L\'evy-Feller type ∂tα(x,t;θ)=-(-)α2( iπθ2 H)α(x,t;θ) involving the fractional Laplacian -(-)α2 of order α, with 2m≤ α <2m+2 (m∈ N), and the exponentiation operator ( iπθ2 H) as the hypercomplex counterpart of the fractional Riesz-Hilbert transform carrying the skewness parameter θ, with values in the range |θ|≤ \α-2m,2m+2-α\. Such model problem permits us to obtain hypercomplex counterparts for the fundamental solutions of higher-order heat-type equations ∂t FM(x,t)=M(∂x)M FM(x,t) (M=2,3,…) in case where the even powers resp. odd powers D2m=(-)m (M=α=2m) resp. D2m+1=(-)m+12H (M=α=2m+1) of D are being considered.