Interplay between percolation and glassiness in the random Lorentz gas.

dc.contributor.author

Biroli, Giulio

dc.contributor.author

Charbonneau, Patrick

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Corwin, Eric I

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Hu, Yi

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Ikeda, Harukuni

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Szamel, Grzegorz

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Zamponi, Francesco

dc.date.accessioned

2022-05-02T17:25:33Z

dc.date.available

2022-05-02T17:25:33Z

dc.date.issued

2021-03

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2022-05-02T17:25:33Z

dc.description.abstract

The random Lorentz gas (RLG) is a minimal model of transport in heterogeneous media that exhibits a continuous localization transition controlled by void space percolation. The RLG also provides a toy model of particle caging, which is known to be relevant for describing the discontinuous dynamical transition of glasses. In order to clarify the interplay between the seemingly incompatible percolation and caging descriptions of the RLG, we consider its exact mean-field solution in the infinite-dimensional d→∞ limit and perform numerics in d=2...20. We find that for sufficiently high d the mean-field caging transition precedes and prevents the percolation transition, which only happens on timescales diverging with d. We further show that activated processes related to rare cage escapes destroy the glass transition in finite dimensions, leading to a rich interplay between glassiness and percolation physics. This advance suggests that the RLG can be used as a toy model to develop a first-principle description of particle hopping in structural glasses.

dc.identifier.issn

2470-0045

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2470-0053

dc.identifier.uri

https://hdl.handle.net/10161/24985

dc.language

eng

dc.publisher

American Physical Society (APS)

dc.relation.ispartof

Physical review. E

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10.1103/physreve.103.l030104

dc.subject

cond-mat.stat-mech

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cond-mat.stat-mech

dc.title

Interplay between percolation and glassiness in the random Lorentz gas.

dc.type

Journal article

duke.contributor.orcid

Charbonneau, Patrick|0000-0001-7174-0821

pubs.begin-page

L030104

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3

pubs.organisational-group

Duke

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Trinity College of Arts & Sciences

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Chemistry

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Physics

pubs.publication-status

Published

pubs.volume

103

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