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Correlation of plastic events with local structure in jammed packings across spatial dimensions

Sean A. Ridout, Jason W. Rocks, Andrea J. Liu

2022Proceedings of the National Academy of Sciences16 citationsDOIOpen Access PDF

Abstract

In frictionless jammed packings, existing evidence suggests a picture in which localized physics dominates in low spatial dimensions, d = 2, 3, but quickly loses relevance as d rises, replaced by spatially extended mean-field behavior. For example, quasilocalized low-energy vibrational modes and low-coordination particles associated with deviation from mean-field behavior (rattlers and bucklers) all vanish rapidly with increasing d. These results suggest that localized rearrangements, which are associated with low-energy vibrational modes, correlated with local structure, and dominant in low dimensions, should give way in higher d to extended rearrangements uncorrelated with local structure. Here, we use machine learning to analyze simulations of jammed packings under athermal, quasistatic shear, identifying a local structural variable, softness, that correlates with rearrangements in dimensions d = 2 to d = 5. We find that softness—and even just the local coordination number Z—is essentially equally predictive of rearrangements in all d studied. This result provides direct evidence that local structure plays an important role in higher d, suggesting a modified picture for the dimensional cross-over to mean-field theory.

Topics & Concepts

UncorrelatedQuasistatic processLocal structureStatistical physicsPhysicsRelevance (law)MathematicsCorrelationLocal symmetrySpatial correlationMode (computer interface)Spatial dependenceGeometrySpatial relationshipMaterial Dynamics and PropertiesTheoretical and Computational PhysicsAdvanced Physical and Chemical Molecular Interactions
Correlation of plastic events with local structure in jammed packings across spatial dimensions | Litcius