Saved in:
Bibliographic Details
Main Authors: Yang, Fan, Yin, Jun
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2501.08608
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866912323799613440
author Yang, Fan
Yin, Jun
author_facet Yang, Fan
Yin, Jun
contents We consider a natural class of extensions of the Anderson model on $\mathbb Z^d$, called random block Schrödinger operators (RBSOs), defined on the $d$-dimensional torus $(\mathbb Z/L\mathbb Z)^d$. These operators take the form $H=V+λΨ$, where $V$ is a diagonal block matrix whose diagonal blocks are i.i.d. $W^d\times W^d$ GUE, representing a random block potential, $Ψ$ describes interactions between neighboring blocks, and $λ\ll 1$ is a small coupling parameter (making $H$ a perturbation of $V$). We focus on three specific RBSOs: (1) the block Anderson model, where $Ψ$ is the discrete Laplacian on $(\mathbb Z/L\mathbb Z)^d$; (2) the Anderson orbital model, where $Ψ$ is a block Laplacian operator; (3) the Wegner orbital model, where the nearest-neighbor blocks of $Ψ$ are themselves random matrices. Assuming $d\ge 7$ and $W\ge L^\varepsilon$ for a small constant $\varepsilon>0$, and under a certain lower bound on $λ$, we establish delocalization and quantum unique ergodicity for bulk eigenvectors, along with quantum diffusion estimates for the Green's function. Combined with the localization results of arXiv:1608.02922, our results rigorously demonstrate the existence of an Anderson localization-delocalization transition for RBSOs as $λ$ varies. Our proof is based on the $T$-expansion method and the concept of self-energy renormalization, originally developed in the study of random band matrices in arXiv:2104.12048. In addition, we introduce a conceptually novel idea, called coupling renormalization, which extends the notion of self-energy renormalization. While this phenomenon is well-known in quantum field theory, it is identified here for the first time in the context of random Schrödinger operators. We expect that our methods can be extended to models with real or non-Gaussian block potentials, as well as more general forms of interactions.
format Preprint
id arxiv_https___arxiv_org_abs_2501_08608
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Delocalization of a general class of random block Schrödinger operators
Yang, Fan
Yin, Jun
Probability
Mathematical Physics
We consider a natural class of extensions of the Anderson model on $\mathbb Z^d$, called random block Schrödinger operators (RBSOs), defined on the $d$-dimensional torus $(\mathbb Z/L\mathbb Z)^d$. These operators take the form $H=V+λΨ$, where $V$ is a diagonal block matrix whose diagonal blocks are i.i.d. $W^d\times W^d$ GUE, representing a random block potential, $Ψ$ describes interactions between neighboring blocks, and $λ\ll 1$ is a small coupling parameter (making $H$ a perturbation of $V$). We focus on three specific RBSOs: (1) the block Anderson model, where $Ψ$ is the discrete Laplacian on $(\mathbb Z/L\mathbb Z)^d$; (2) the Anderson orbital model, where $Ψ$ is a block Laplacian operator; (3) the Wegner orbital model, where the nearest-neighbor blocks of $Ψ$ are themselves random matrices. Assuming $d\ge 7$ and $W\ge L^\varepsilon$ for a small constant $\varepsilon>0$, and under a certain lower bound on $λ$, we establish delocalization and quantum unique ergodicity for bulk eigenvectors, along with quantum diffusion estimates for the Green's function. Combined with the localization results of arXiv:1608.02922, our results rigorously demonstrate the existence of an Anderson localization-delocalization transition for RBSOs as $λ$ varies. Our proof is based on the $T$-expansion method and the concept of self-energy renormalization, originally developed in the study of random band matrices in arXiv:2104.12048. In addition, we introduce a conceptually novel idea, called coupling renormalization, which extends the notion of self-energy renormalization. While this phenomenon is well-known in quantum field theory, it is identified here for the first time in the context of random Schrödinger operators. We expect that our methods can be extended to models with real or non-Gaussian block potentials, as well as more general forms of interactions.
title Delocalization of a general class of random block Schrödinger operators
topic Probability
Mathematical Physics
url https://arxiv.org/abs/2501.08608