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Bibliographic Details
Main Authors: O'Brien, Liam, Refael, Gil
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2304.14449
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author O'Brien, Liam
Refael, Gil
author_facet O'Brien, Liam
Refael, Gil
contents Identifying and measuring the "localization length'' in many-body systems in the vicinity of a many-body localization transition is difficult. Following Hatano and Nelson, a recent work (Heuben, White, Refael, PRB 103, 064201 (2021)) introduced an "imaginary vector potential'' to a disordered ring of interacting fermions, in order to define a many-body localization length (corresponding, in the non-interacting case, to the end-to-end Green's function of the hermitian system). We extend these results, by connecting this localization length to the length scale appearing in the avalanche model of delocalization. We use this connection to derive the distribution of the localization length at the MBL transition, finding good agreement with our numerical observations. Our results demonstrate how a localization length defined as such probes the localization of the underlying ring, without the need to explicitly construct the l-bits.
format Preprint
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institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Probing localization properties of many-body Hamiltonians via an imaginary vector potential
O'Brien, Liam
Refael, Gil
Disordered Systems and Neural Networks
Identifying and measuring the "localization length'' in many-body systems in the vicinity of a many-body localization transition is difficult. Following Hatano and Nelson, a recent work (Heuben, White, Refael, PRB 103, 064201 (2021)) introduced an "imaginary vector potential'' to a disordered ring of interacting fermions, in order to define a many-body localization length (corresponding, in the non-interacting case, to the end-to-end Green's function of the hermitian system). We extend these results, by connecting this localization length to the length scale appearing in the avalanche model of delocalization. We use this connection to derive the distribution of the localization length at the MBL transition, finding good agreement with our numerical observations. Our results demonstrate how a localization length defined as such probes the localization of the underlying ring, without the need to explicitly construct the l-bits.
title Probing localization properties of many-body Hamiltonians via an imaginary vector potential
topic Disordered Systems and Neural Networks
url https://arxiv.org/abs/2304.14449