Anderson localization and ergodicity on random regular graphs Article Swipe

View

Related Concepts

Delocalized electron Diagonal Ergodic theory Ergodicity Mathematics Crossover Statistical physics Combinatorics Phase transition Lattice (music) Inverse Random graph Physics Discrete mathematics Quantum mechanics Pure mathematics Computer science Statistics Graph Geometry Acoustics Artificial intelligence

K. S. Tikhonov , A. D. Mirlin , M. A. Skvortsov ·

YOU? · · 2016 · Open Access · · DOI: https://doi.org/10.1103/physrevb.94.220203 · OA: W2340811749

A numerical study of Anderson transition on random regular graphs (RRG) with diagonal disorder is performed. The problem can be described as a tight-binding model on a lattice with N sites that is locally a tree with constant connectivity. In certain sense, the RRG ensemble can be seen as infinite-dimensional ($d\to\infty$) cousin of Anderson model in d dimensions. We focus on the delocalized side of the transition and stress the importance of finite-size effects. We show that the data can be interpreted in terms of the finite-size crossover from small ($N\ll N_c$) to large ($N\gg N_c$) system, where $N_c$ is the correlation volume diverging exponentially at the transition. A distinct feature of this crossover is a nonmonotonicity of the spectral and wavefunction statistics, which is related to properties of the critical phase in the studied model and renders the finite-size analysis highly non-trivial. Our results support an analytical prediction that states in the delocalized phase (and at $N\gg N_c$) are ergodic in the sense that their inverse participation ratio scales as $1/N$.