Percolated Strain Networks and Universal Scaling Properties of Strain Glasses

Hongxiang Zong; Haijun Wu; Xuefei Tao; Deqing Xue; Jun Sun; Stephen J. Pennycook; Tai Min; Zhenyu Zhang; Xiangdong Ding

doi:10.1103/PhysRevLett.123.015701

Percolated Strain Networks and Universal Scaling Properties of Strain Glasses

Hongxiang Zong
, Haijun Wu
, Xuefei Tao
, Deqing Xue
, Jun Sun
, Stephen J. Pennycook
, Tai Min
, Zhenyu Zhang
, Xiangdong Ding

School of Materials Science and Engineering

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

29 Scopus citations

Abstract

Strain glass is being established as a conceptually new state of matter in highly doped alloys, yet the understanding of its microscopic formation mechanism remains elusive. Here, we use a combined numerical and experimental approach to establish, for the first time, that the formation of strain glasses actually proceeds via the gradual percolation of strain clusters, namely, localized strain clusters that expand to reach the percolating state. Furthermore, our simulation studies of a wide variety of specific materials systems unambiguously reveal the existence of distinct scaling properties and universal behavior in the physical observables characterizing the glass transition, as obeyed by many existing experimental findings. The present work effectively enriches our understanding of the underlying physical principles governing glassy disordered materials.

Original language	English
Article number	015701
Journal	Physical Review Letters
Volume	123
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevLett.123.015701
State	Published - 3 Jul 2019

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10.1103/PhysRevLett.123.015701

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abstract = "Strain glass is being established as a conceptually new state of matter in highly doped alloys, yet the understanding of its microscopic formation mechanism remains elusive. Here, we use a combined numerical and experimental approach to establish, for the first time, that the formation of strain glasses actually proceeds via the gradual percolation of strain clusters, namely, localized strain clusters that expand to reach the percolating state. Furthermore, our simulation studies of a wide variety of specific materials systems unambiguously reveal the existence of distinct scaling properties and universal behavior in the physical observables characterizing the glass transition, as obeyed by many existing experimental findings. The present work effectively enriches our understanding of the underlying physical principles governing glassy disordered materials.",

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AU - Zong, Hongxiang

AU - Wu, Haijun

AU - Tao, Xuefei

AU - Xue, Deqing

AU - Sun, Jun

AU - Pennycook, Stephen J.

AU - Min, Tai

AU - Zhang, Zhenyu

AU - Ding, Xiangdong

PY - 2019/7/3

Y1 - 2019/7/3

N2 - Strain glass is being established as a conceptually new state of matter in highly doped alloys, yet the understanding of its microscopic formation mechanism remains elusive. Here, we use a combined numerical and experimental approach to establish, for the first time, that the formation of strain glasses actually proceeds via the gradual percolation of strain clusters, namely, localized strain clusters that expand to reach the percolating state. Furthermore, our simulation studies of a wide variety of specific materials systems unambiguously reveal the existence of distinct scaling properties and universal behavior in the physical observables characterizing the glass transition, as obeyed by many existing experimental findings. The present work effectively enriches our understanding of the underlying physical principles governing glassy disordered materials.

AB - Strain glass is being established as a conceptually new state of matter in highly doped alloys, yet the understanding of its microscopic formation mechanism remains elusive. Here, we use a combined numerical and experimental approach to establish, for the first time, that the formation of strain glasses actually proceeds via the gradual percolation of strain clusters, namely, localized strain clusters that expand to reach the percolating state. Furthermore, our simulation studies of a wide variety of specific materials systems unambiguously reveal the existence of distinct scaling properties and universal behavior in the physical observables characterizing the glass transition, as obeyed by many existing experimental findings. The present work effectively enriches our understanding of the underlying physical principles governing glassy disordered materials.

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JO - Physical Review Letters

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Percolated Strain Networks and Universal Scaling Properties of Strain Glasses

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