The structural origin of the hard-sphere glass transition in granular packing

Chengjie Xia; Jindong Li; Yixin Cao; Binquan Kou; Xianghui Xiao; Kamel Fezzaa; Tiqiao Xiao; Yujie Wang

doi:10.1038/ncomms9409

The structural origin of the hard-sphere glass transition in granular packing

Chengjie Xia
, Jindong Li
, Yixin Cao
, Binquan Kou
, Xianghui Xiao
, Kamel Fezzaa
, Tiqiao Xiao
, Yujie Wang^*

^*Corresponding author for this work

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

73 Scopus citations

Abstract

Glass transition is accompanied by a rapid growth of the structural relaxation time and a concomitant decrease of configurational entropy. It remains unclear whether the transition has a thermodynamic origin, and whether the dynamic arrest is associated with the growth of a certain static order. Using granular packing as a model hard-sphere glass, we show the glass transition as a thermodynamic phase transition with a a € hiddena € polytetrahedral order. This polytetrahedral order is spatially correlated with the slow dynamics. It is geometrically frustrated and has a peculiar fractal dimension. Additionally, as the packing fraction increases, its growth follows an entropy-driven nucleation process, similar to that of the random first-order transition theory. Our study essentially identifies a long-sought-After structural glass order in hard-sphere glasses.

Original language	English
Article number	8409
Journal	Nature Communications
Volume	6
DOIs	https://doi.org/10.1038/ncomms9409
State	Published - 28 Sep 2015
Externally published	Yes

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title = "The structural origin of the hard-sphere glass transition in granular packing",

abstract = "Glass transition is accompanied by a rapid growth of the structural relaxation time and a concomitant decrease of configurational entropy. It remains unclear whether the transition has a thermodynamic origin, and whether the dynamic arrest is associated with the growth of a certain static order. Using granular packing as a model hard-sphere glass, we show the glass transition as a thermodynamic phase transition with a a € hiddena € polytetrahedral order. This polytetrahedral order is spatially correlated with the slow dynamics. It is geometrically frustrated and has a peculiar fractal dimension. Additionally, as the packing fraction increases, its growth follows an entropy-driven nucleation process, similar to that of the random first-order transition theory. Our study essentially identifies a long-sought-After structural glass order in hard-sphere glasses.",

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T1 - The structural origin of the hard-sphere glass transition in granular packing

AU - Xia, Chengjie

AU - Li, Jindong

AU - Cao, Yixin

AU - Kou, Binquan

AU - Xiao, Xianghui

AU - Fezzaa, Kamel

AU - Xiao, Tiqiao

AU - Wang, Yujie

PY - 2015/9/28

Y1 - 2015/9/28

N2 - Glass transition is accompanied by a rapid growth of the structural relaxation time and a concomitant decrease of configurational entropy. It remains unclear whether the transition has a thermodynamic origin, and whether the dynamic arrest is associated with the growth of a certain static order. Using granular packing as a model hard-sphere glass, we show the glass transition as a thermodynamic phase transition with a a € hiddena € polytetrahedral order. This polytetrahedral order is spatially correlated with the slow dynamics. It is geometrically frustrated and has a peculiar fractal dimension. Additionally, as the packing fraction increases, its growth follows an entropy-driven nucleation process, similar to that of the random first-order transition theory. Our study essentially identifies a long-sought-After structural glass order in hard-sphere glasses.

AB - Glass transition is accompanied by a rapid growth of the structural relaxation time and a concomitant decrease of configurational entropy. It remains unclear whether the transition has a thermodynamic origin, and whether the dynamic arrest is associated with the growth of a certain static order. Using granular packing as a model hard-sphere glass, we show the glass transition as a thermodynamic phase transition with a a € hiddena € polytetrahedral order. This polytetrahedral order is spatially correlated with the slow dynamics. It is geometrically frustrated and has a peculiar fractal dimension. Additionally, as the packing fraction increases, its growth follows an entropy-driven nucleation process, similar to that of the random first-order transition theory. Our study essentially identifies a long-sought-After structural glass order in hard-sphere glasses.

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DO - 10.1038/ncomms9409

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SN - 2041-1723

VL - 6

JO - Nature Communications

JF - Nature Communications

M1 - 8409

ER -

The structural origin of the hard-sphere glass transition in granular packing

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