Inherent-Structure Dynamics and Diffusion in Liquids

C. Donati; D. Frantz; E. La Nave; F.H. Stillinger; F.H. Stillinger; F.H. Stillinger; G. Adam; I. Andricioaei; J. Chowdhary; L. Angelani; M. Goldstein; M. Miller; R. LaViolette; S. Buchner; S. Sastry; T. Keyes; T. Keyes; T. Keyes; W. Goetze; Wu-Xiong Li

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Inherent-Structure Dynamics and Diffusion in Liquids

Authors: C. Donati
D. Frantz
E. La Nave
F.H. Stillinger
F.H. Stillinger
F.H. Stillinger
G. Adam
I. Andricioaei
J. Chowdhary
L. Angelani
M. Goldstein
M. Miller
R. LaViolette
S. Buchner
S. Sastry
T. Keyes
T. Keyes
T. Keyes
W. Goetze
Wu-Xiong Li
Publication date: 5 December 2000
Publisher: 'American Physical Society (APS)'
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Abstract

The self-diffusion constant D is expressed in terms of transitions among the local minima of the potential (inherent structure, IS) and their correlations. The formulae are evaluated and tested against simulation in the supercooled, unit-density Lennard-Jones liquid. The approximation of uncorrelated IS-transition (IST) vectors, D_{0}, greatly exceeds D in the upper temperature range, but merges with simulation at reduced T ~ 0.50. Since uncorrelated IST are associated with a hopping mechanism, the condition D ~ D_{0} provides a new way to identify the crossover to hopping. The results suggest that theories of diffusion in deeply supercooled liquids may be based on weakly correlated IST.Comment: submitted to PR

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