Local Dynamical Heterogeneity in Simple Glass Formers.

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2022-04

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Abstract

We study the local dynamical fluctuations in glass-forming models of particles embedded in d-dimensional space, in the mean-field limit of d→∞. Our analytical calculation reveals that single-particle observables, such as squared particle displacements, display divergent fluctuations around the dynamical (or mode-coupling) transition, due to the emergence of nontrivial correlations between displacements along different directions. This effect notably gives rise to a divergent non-Gaussian parameter, α_{2}. The d→∞ local dynamics therefore becomes quite rich upon approaching the glass transition. The finite-d remnant of this phenomenon further provides a long sought-after, first-principle explanation for the growth of α_{2} around the glass transition that is not based on multiparticle correlations.

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10.1103/physrevlett.128.175501

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Biroli, Giulio, Patrick Charbonneau, Giampaolo Folena, Yi Hu and Francesco Zamponi (2022). Local Dynamical Heterogeneity in Simple Glass Formers. Physical review letters, 128(17). p. 175501. 10.1103/physrevlett.128.175501 Retrieved from https://hdl.handle.net/10161/25101.

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Charbonneau

Patrick Charbonneau

Professor of Chemistry

Professor Charbonneau studies soft matter. His work combines theory and simulation to understand the glass problem, protein crystallization, microphase formation, and colloidal assembly in external fields.


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