Logarithmic, noise-induced dynamics in the Anderson insulator

Talía L.M. Lezama; Yevgeny Bar Lev

doi:https://doi.org/10.21468/SciPostPhys.12.5.174

Logarithmic, noise-induced dynamics in the Anderson insulator

Talía L.M. Lezama, Yevgeny Bar Lev

Department of Physics

Ben-Gurion University of the Negev

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

Abstract

We study the dynamical behavior of the one-dimensional Anderson insulator in the presence of a local noise. We show that the noise induces logarithmically slow energy and entanglement growth, until the system reaches an infinite-temperature state, where both quantities saturate to extensive values. The saturation value of the entanglement entropy approaches the average entanglement entropy over all possible product states. At infinite temperature, we find that a density excitation spreads logarithmically with time, without any signs of asymptotic diffusive behavior. In addition, we provide a theoretical picture which qualitatively reproduces the phenomenology of particle transport.

Original language	American English
Article number	174
Journal	SCIPOST PHYSICS
Volume	12
Issue number	5
DOIs	https://doi.org/10.21468/SciPostPhys.12.5.174
State	Published - 25 May 2022

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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https://doi.org/10.21468/SciPostPhys.12.5.174

Cite this

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title = "Logarithmic, noise-induced dynamics in the Anderson insulator",

abstract = "We study the dynamical behavior of the one-dimensional Anderson insulator in the presence of a local noise. We show that the noise induces logarithmically slow energy and entanglement growth, until the system reaches an infinite-temperature state, where both quantities saturate to extensive values. The saturation value of the entanglement entropy approaches the average entanglement entropy over all possible product states. At infinite temperature, we find that a density excitation spreads logarithmically with time, without any signs of asymptotic diffusive behavior. In addition, we provide a theoretical picture which qualitatively reproduces the phenomenology of particle transport.",

author = "Lezama, {Tal{\'i}a L.M.} and Lev, {Yevgeny Bar}",

note = "Funding Information: We thank Lev Vidmar for bringing to our attention Ref. [50], where the average entanglement entropy over all possible product states is obtained analytically. This research was supported by a grant from the United States-Israel Binational Foundation (BSF, Grant No. 2019644), Jerusalem, Israel, and the United States National Science Foundation (NSF, Grant No. DMR-1936006), and by the Israel Science Foundation (grants No. 527/19 and 218/19). TLML acknowledges funding from the Kreitman fellowship. Publisher Copyright: {\textcopyright} 2022 SciPost Foundation. All rights reserved.",

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N2 - We study the dynamical behavior of the one-dimensional Anderson insulator in the presence of a local noise. We show that the noise induces logarithmically slow energy and entanglement growth, until the system reaches an infinite-temperature state, where both quantities saturate to extensive values. The saturation value of the entanglement entropy approaches the average entanglement entropy over all possible product states. At infinite temperature, we find that a density excitation spreads logarithmically with time, without any signs of asymptotic diffusive behavior. In addition, we provide a theoretical picture which qualitatively reproduces the phenomenology of particle transport.

AB - We study the dynamical behavior of the one-dimensional Anderson insulator in the presence of a local noise. We show that the noise induces logarithmically slow energy and entanglement growth, until the system reaches an infinite-temperature state, where both quantities saturate to extensive values. The saturation value of the entanglement entropy approaches the average entanglement entropy over all possible product states. At infinite temperature, we find that a density excitation spreads logarithmically with time, without any signs of asymptotic diffusive behavior. In addition, we provide a theoretical picture which qualitatively reproduces the phenomenology of particle transport.

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Logarithmic, noise-induced dynamics in the Anderson insulator

Abstract

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