An approach to anomalous diffusion in the n-dimensional space generated by a self-similar Laplacian

Abstract

We analyze a quasi-continuous linear chain with self-similar distribution of harmonic interparticle springs as recently introduced for one dimension (Michelitsch et al., Phys. Rev. E 80, 011135 (2009)). We define a continuum limit for one dimension and generalize it to n=1,2,3,.. dimensions of the physical space. Application of Hamilton's (variational) principle defines then a self-similar and as consequence non-local Laplacian operator for the n-dimensional space where we proof its ellipticity and its accordance (up to a strictly positive prefactor) with the fractional Laplacian -(-)α2. By employing this Laplacian we establish a Fokker Planck diffusion equation: We show that this Laplacian generates spatially isotropic L\'evi stable distributions which correspond to L\'evi flights in n-dimensions. In the limit of large scaled times t/rα >>1 the obtained distributions exhibit an algebraic decay t-nα → 0 independent from the initial distribution and spacepoint. This universal scaling depends only on the ratio n/α of the dimension n of the physical space and the L\'evi parameter α.