Energy landscape-driven non-equilibrium evolution of inherent structure in disordered material

Energy landscape-driven non-equilibrium evolution of inherent structure in disordered material

Fundamental understanding of glass dynamics is challenging owing to their complex non-equilibrium nature and thus the multi-dimensional potential energy landscape. Here, Fanet al. present a model to explore the glass energy landscape driven by thermal activation and relaxation, which are temporally...

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Main Authors: Yue Fan, Takuya Iwashita, Takeshi Egami
Format: Article
Language:English
Published: Nature Publishing Group 2017-05-01
Series:Nature Communications
Online Access:https://doi.org/10.1038/ncomms15417
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spelling doaj-15a305b2d60d49deb4b2810efed544392021-05-11T07:15:00ZengNature Publishing GroupNature Communications2041-17232017-05-01811710.1038/ncomms15417Energy landscape-driven non-equilibrium evolution of inherent structure in disordered materialYue Fan0Takuya Iwashita1Takeshi Egami2Department of Mechanical Engineering, University of MichiganDivision of Natural Sciences, Oita UniversityShull Wollan Center – Joint Institute for Neutron SciencesFundamental understanding of glass dynamics is challenging owing to their complex non-equilibrium nature and thus the multi-dimensional potential energy landscape. Here, Fanet al. present a model to explore the glass energy landscape driven by thermal activation and relaxation, which are temporally decoupled.https://doi.org/10.1038/ncomms15417
collection DOAJ
language English
format Article
sources DOAJ
author Yue Fan
Takuya Iwashita
Takeshi Egami
spellingShingle Yue Fan
Takuya Iwashita
Takeshi Egami
Energy landscape-driven non-equilibrium evolution of inherent structure in disordered material
Nature Communications
author_facet Yue Fan
Takuya Iwashita
Takeshi Egami
author_sort Yue Fan
title Energy landscape-driven non-equilibrium evolution of inherent structure in disordered material
title_short Energy landscape-driven non-equilibrium evolution of inherent structure in disordered material
title_full Energy landscape-driven non-equilibrium evolution of inherent structure in disordered material
title_fullStr Energy landscape-driven non-equilibrium evolution of inherent structure in disordered material
title_full_unstemmed Energy landscape-driven non-equilibrium evolution of inherent structure in disordered material
title_sort energy landscape-driven non-equilibrium evolution of inherent structure in disordered material
publisher Nature Publishing Group
series Nature Communications
issn 2041-1723
publishDate 2017-05-01
description Fundamental understanding of glass dynamics is challenging owing to their complex non-equilibrium nature and thus the multi-dimensional potential energy landscape. Here, Fanet al. present a model to explore the glass energy landscape driven by thermal activation and relaxation, which are temporally decoupled.
url https://doi.org/10.1038/ncomms15417
work_keys_str_mv AT yuefan energylandscapedrivennonequilibriumevolutionofinherentstructureindisorderedmaterial
AT takuyaiwashita energylandscapedrivennonequilibriumevolutionofinherentstructureindisorderedmaterial
AT takeshiegami energylandscapedrivennonequilibriumevolutionofinherentstructureindisorderedmaterial
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