Structural Transformation between a Nematic Loose Packing and a Randomly Stacked Close Packing of Granular Disks

Yunhao Ding; Jing Yang; Chenyang Wang; Zhichao Wang; Jianqi Li; Bingwen Hu; Chengjie Xia

doi:10.1103/PhysRevLett.131.098202

Structural Transformation between a Nematic Loose Packing and a Randomly Stacked Close Packing of Granular Disks

Yunhao Ding, Jing Yang, Chenyang Wang, Zhichao Wang, Jianqi Li, Bingwen Hu, Chengjie Xia

School of Physics and Electronic Science

East China Normal University

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

2 Scopus citations

Abstract

Packing structures of granular disks are reconstructed using magnetic resonance imaging techniques. As packing fraction increases, the packing structure transforms from a nematic loose packing to a dense packing with randomly oriented stacks. According to our model based on Edwards' volume ensemble, stack structures are statistically favored when the effective temperature decreases, which has a lower structural anisotropy than single disks, and brings down the global orientational order consequently. This mechanism identified in athermal granular materials can help us understand the nonergodic characteristics of disklike particle assemblies such as discotic mesogens and clays.

Original language	English
Article number	098202
Journal	Physical Review Letters
Volume	131
Issue number	9
DOIs	https://doi.org/10.1103/PhysRevLett.131.098202
State	Published - 1 Sep 2023

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10.1103/PhysRevLett.131.098202

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title = "Structural Transformation between a Nematic Loose Packing and a Randomly Stacked Close Packing of Granular Disks",

abstract = "Packing structures of granular disks are reconstructed using magnetic resonance imaging techniques. As packing fraction increases, the packing structure transforms from a nematic loose packing to a dense packing with randomly oriented stacks. According to our model based on Edwards' volume ensemble, stack structures are statistically favored when the effective temperature decreases, which has a lower structural anisotropy than single disks, and brings down the global orientational order consequently. This mechanism identified in athermal granular materials can help us understand the nonergodic characteristics of disklike particle assemblies such as discotic mesogens and clays.",

author = "Yunhao Ding and Jing Yang and Chenyang Wang and Zhichao Wang and Jianqi Li and Bingwen Hu and Chengjie Xia",

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AU - Ding, Yunhao

AU - Yang, Jing

AU - Wang, Chenyang

AU - Wang, Zhichao

AU - Li, Jianqi

AU - Hu, Bingwen

AU - Xia, Chengjie

PY - 2023/9/1

Y1 - 2023/9/1

N2 - Packing structures of granular disks are reconstructed using magnetic resonance imaging techniques. As packing fraction increases, the packing structure transforms from a nematic loose packing to a dense packing with randomly oriented stacks. According to our model based on Edwards' volume ensemble, stack structures are statistically favored when the effective temperature decreases, which has a lower structural anisotropy than single disks, and brings down the global orientational order consequently. This mechanism identified in athermal granular materials can help us understand the nonergodic characteristics of disklike particle assemblies such as discotic mesogens and clays.

AB - Packing structures of granular disks are reconstructed using magnetic resonance imaging techniques. As packing fraction increases, the packing structure transforms from a nematic loose packing to a dense packing with randomly oriented stacks. According to our model based on Edwards' volume ensemble, stack structures are statistically favored when the effective temperature decreases, which has a lower structural anisotropy than single disks, and brings down the global orientational order consequently. This mechanism identified in athermal granular materials can help us understand the nonergodic characteristics of disklike particle assemblies such as discotic mesogens and clays.

UR - https://www.scopus.com/pages/publications/85171697945

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DO - 10.1103/PhysRevLett.131.098202

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VL - 131

JO - Physical Review Letters

JF - Physical Review Letters

IS - 9

M1 - 098202

ER -

Structural Transformation between a Nematic Loose Packing and a Randomly Stacked Close Packing of Granular Disks

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