Penetration of surface effects on structural relaxation and particle hops in glassy films

Qiang Zhai; Hai Yao Deng; Xin Yuan Gao; Leo S.I. Lam; Sen Yang; Ke Yan; Chi Hang Lam

doi:10.1063/5.0271966

Penetration of surface effects on structural relaxation and particle hops in glassy films

Qiang Zhai
, Hai Yao Deng
, Xin Yuan Gao
, Leo S.I. Lam
, Sen Yang
, Ke Yan
, Chi Hang Lam

Research output: Journal article publication › Journal article › Academic research › peer-review

1 Citation (Scopus)

Abstract

A free surface induces enhanced dynamics in glass formers. We study the dynamical enhancement of glassy films with a distinguishable-particle lattice model of glass free of elastic effects. We demonstrate that the thickness of the surface mobile layer depends on temperature differently under different definitions, although all are based on local structure relaxation rate. The rate can be fitted to a double exponential form with an exponential-of-power-law tail. Our approach and results exclude elasticity as the unique mechanism for the tail. Layer-resolved particle hopping rate, potentially a key measure for activated hopping, is also studied but it exhibits much shallower surface effects.

Original language	English
Article number	234502
Journal	Journal of Chemical Physics
Volume	162
Issue number	23
DOIs	https://doi.org/10.1063/5.0271966
Publication status	Published - 21 Jun 2025

ASJC Scopus subject areas

General Physics and Astronomy
Physical and Theoretical Chemistry

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10.1063/5.0271966

http://hdl.handle.net/10397/113900

Cite this

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title = "Penetration of surface effects on structural relaxation and particle hops in glassy films",

abstract = "A free surface induces enhanced dynamics in glass formers. We study the dynamical enhancement of glassy films with a distinguishable-particle lattice model of glass free of elastic effects. We demonstrate that the thickness of the surface mobile layer depends on temperature differently under different definitions, although all are based on local structure relaxation rate. The rate can be fitted to a double exponential form with an exponential-of-power-law tail. Our approach and results exclude elasticity as the unique mechanism for the tail. Layer-resolved particle hopping rate, potentially a key measure for activated hopping, is also studied but it exhibits much shallower surface effects.",

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AU - Zhai, Qiang

AU - Deng, Hai Yao

AU - Gao, Xin Yuan

AU - Lam, Leo S.I.

AU - Yang, Sen

AU - Yan, Ke

AU - Lam, Chi Hang

PY - 2025/6/21

Y1 - 2025/6/21

N2 - A free surface induces enhanced dynamics in glass formers. We study the dynamical enhancement of glassy films with a distinguishable-particle lattice model of glass free of elastic effects. We demonstrate that the thickness of the surface mobile layer depends on temperature differently under different definitions, although all are based on local structure relaxation rate. The rate can be fitted to a double exponential form with an exponential-of-power-law tail. Our approach and results exclude elasticity as the unique mechanism for the tail. Layer-resolved particle hopping rate, potentially a key measure for activated hopping, is also studied but it exhibits much shallower surface effects.

AB - A free surface induces enhanced dynamics in glass formers. We study the dynamical enhancement of glassy films with a distinguishable-particle lattice model of glass free of elastic effects. We demonstrate that the thickness of the surface mobile layer depends on temperature differently under different definitions, although all are based on local structure relaxation rate. The rate can be fitted to a double exponential form with an exponential-of-power-law tail. Our approach and results exclude elasticity as the unique mechanism for the tail. Layer-resolved particle hopping rate, potentially a key measure for activated hopping, is also studied but it exhibits much shallower surface effects.

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JO - Journal of Chemical Physics

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ER -

Penetration of surface effects on structural relaxation and particle hops in glassy films

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