Recursive Algorithm to the Centroid of Free Area for Inherent Structure and Hopping Motion in Deeply Supercooled Binary Hard Disk Systems

TL;DR

This paper introduces ReCFA, a novel recursive algorithm for identifying inherent structures in hard disk systems, improving understanding of relaxation dynamics and hopping motions in supercooled and jammed states.

Contribution

ReCFA is a new recursive method that effectively captures inherent structures and hopping motions in hard disk systems, addressing challenges posed by discontinuous potentials.

Findings

ReCFA outperforms traditional methods in capturing entropic effects.

Configurations from ReCFA show realistic particle displacements similar to soft systems.

ReCFA effectively identifies hopping motions between metastable states.

Abstract

Inherent structures, derived by eliminating thermal fluctuations from complex trajectories, illuminate fundamental mechanisms underlying structural relaxation and dynamic heterogeneity in dense glassy systems. However, determining these structures in hard disk/sphere systems presents unique challenges due to the discontinuous nature of inter-particle potentials and resultant flat potential energy landscapes. To address this limitation, we introduce the Recursive Centroid of Free Area algorithm (ReCFA), a novel approach inspired by a steepest descent method, which computes inherent structure configurations in hard disk systems. We conducted comparative analyses between ReCFA, similar methods, and a conventional time-coarse-graining technique, focusing on string-like hopping motions in supercompressed binary hard disks that emulate supercooled liquid behavior. ReCFA demonstrated notable advantages in capturing entropic contributions. The configurations derived through ReCFA exhibited physically reasonable particle displacements analogous to inherent structures in soft particle systems, effectively identifying hopping motions between metastable basins in jammed states. This ReCFA-based analysis enhances our understanding of relaxation dynamics in highly compressed glassy systems, offering a robust analytical tool for investigating both dynamic and structural characteristics across hard and soft particle systems.