Scattering Expansion for Localization in One Dimension
Abstract
We present a perturbative approach to disordered systems in one spatial dimension that accesses the full range of phase disorder and clarifies the connection between localization and phase information. We consider a long chain of identically disordered scatterers and expand in the reflection strength of any individual scatterer. As an example application, we show analytically that in a discrete-time quantum walk, the localization length can depend non-monotonically on the strength of phase disorder (whereas expanding in weak disorder yields monotonic decrease). More generally, we obtain to all orders in the expansion a particular non-separable form for the joint probability distribution of the transmission coefficient logarithm and reflection phase. Furthermore, we show that for weak local reflection strength, a version of the scaling theory of localization holds: the joint distribution is determined by just three parameters.
Cite
@article{arxiv.2210.07999,
title = {Scattering Expansion for Localization in One Dimension},
author = {Adrian B. Culver and Pratik Sathe and Rahul Roy},
journal= {arXiv preprint arXiv:2210.07999},
year = {2024}
}
Comments
5+2 pages, 2 figures; expanded conclusion, minor corrections, published version