Dirac walks on regular trees
Abstract
The study of matter fields on an ensemble of random geometries is a difficult problem still in need of new methods and ideas. We will follow a point of view inspired by probability theory techniques that relies on an expansion of the two point function as a sum over random walks. An analogous expansion for Fermions on non-Euclidean geometries is still lacking. Casiday et al. [\textit{Laplace and Dirac operators on graphs}, Linear and Multilinear Algebra (2022) 1] proposed a classical "Dirac walk" diffusing on vertices and edges of an oriented graph with a square root of the graph Laplacian. In contrast to the simple random walk, each step of the walk is given a sign depending on the orientation of the edge it goes through. In a toy model, we propose here to study the Green functions, spectrum and the spectral dimension of such "Dirac walks" on the Bethe lattice, a -regular tree. The recursive structure of the graph makes the problem exactly solvable. Notably, we find that the spectrum develops a gap and that the spectral dimension of the Dirac walk matches that of the simple random walk ( for and for ).
Cite
@article{arxiv.2312.10881,
title = {Dirac walks on regular trees},
author = {Nicolas Delporte and Saswato Sen and Reiko Toriumi},
journal= {arXiv preprint arXiv:2312.10881},
year = {2024}
}
Comments
43 pages, 20 figures, comments welcome