Anomalous diffusion and Griffiths effects near the many-body localization transition

Kartiek Agarwal; Sarang Gopalakrishnan; Michael Knap; Markus Müller; Eugene Demler

doi:10.1103/PhysRevLett.114.160401

Anomalous diffusion and Griffiths effects near the many-body localization transition

Kartiek Agarwal
, Sarang Gopalakrishnan
, Michael Knap
, Markus Müller
, Eugene Demler

Broad Institute of Harvard University
Institute for Theoretical Atomic, Molecular and Optical Physics
ICTP
University of Basel

Research output: Contribution to journal › Article › peer-review

354 Scopus citations

Abstract

We explore the high-temperature dynamics of the disordered, one-dimensional XXZ model near the many-body localization (MBL) transition, focusing on the delocalized (i.e., "metallic") phase. In the vicinity of the transition, we find that this phase has the following properties: (i) local magnetization fluctuations relax subdiffusively; (ii) the ac conductivity vanishes near zero frequency as a power law; and (iii) the distribution of resistivities becomes increasingly broad at low frequencies, approaching a power law in the zero-frequency limit. We argue that these effects can be understood in a unified way if the metallic phase near the MBL transition is a quantum Griffiths phase. We establish scaling relations between the associated exponents, assuming a scaling form of the spin-diffusion propagator. A phenomenological classical resistor-capacitor model captures all the essential features.

Original language	English
Article number	160401
Journal	Physical Review Letters
Volume	114
Issue number	16
DOIs	https://doi.org/10.1103/PhysRevLett.114.160401
State	Published - 23 Apr 2015
Externally published	Yes

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title = "Anomalous diffusion and Griffiths effects near the many-body localization transition",

abstract = "We explore the high-temperature dynamics of the disordered, one-dimensional XXZ model near the many-body localization (MBL) transition, focusing on the delocalized (i.e., {"}metallic{"}) phase. In the vicinity of the transition, we find that this phase has the following properties: (i) local magnetization fluctuations relax subdiffusively; (ii) the ac conductivity vanishes near zero frequency as a power law; and (iii) the distribution of resistivities becomes increasingly broad at low frequencies, approaching a power law in the zero-frequency limit. We argue that these effects can be understood in a unified way if the metallic phase near the MBL transition is a quantum Griffiths phase. We establish scaling relations between the associated exponents, assuming a scaling form of the spin-diffusion propagator. A phenomenological classical resistor-capacitor model captures all the essential features.",

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T1 - Anomalous diffusion and Griffiths effects near the many-body localization transition

AU - Agarwal, Kartiek

AU - Gopalakrishnan, Sarang

AU - Knap, Michael

AU - Müller, Markus

AU - Demler, Eugene

PY - 2015/4/23

Y1 - 2015/4/23

N2 - We explore the high-temperature dynamics of the disordered, one-dimensional XXZ model near the many-body localization (MBL) transition, focusing on the delocalized (i.e., "metallic") phase. In the vicinity of the transition, we find that this phase has the following properties: (i) local magnetization fluctuations relax subdiffusively; (ii) the ac conductivity vanishes near zero frequency as a power law; and (iii) the distribution of resistivities becomes increasingly broad at low frequencies, approaching a power law in the zero-frequency limit. We argue that these effects can be understood in a unified way if the metallic phase near the MBL transition is a quantum Griffiths phase. We establish scaling relations between the associated exponents, assuming a scaling form of the spin-diffusion propagator. A phenomenological classical resistor-capacitor model captures all the essential features.

AB - We explore the high-temperature dynamics of the disordered, one-dimensional XXZ model near the many-body localization (MBL) transition, focusing on the delocalized (i.e., "metallic") phase. In the vicinity of the transition, we find that this phase has the following properties: (i) local magnetization fluctuations relax subdiffusively; (ii) the ac conductivity vanishes near zero frequency as a power law; and (iii) the distribution of resistivities becomes increasingly broad at low frequencies, approaching a power law in the zero-frequency limit. We argue that these effects can be understood in a unified way if the metallic phase near the MBL transition is a quantum Griffiths phase. We establish scaling relations between the associated exponents, assuming a scaling form of the spin-diffusion propagator. A phenomenological classical resistor-capacitor model captures all the essential features.

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Anomalous diffusion and Griffiths effects near the many-body localization transition

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