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arXiv:2404.04473v2 Announce Type: replace
Abstract: Unraveling the relation between structural information and the dynamic properties of supercooled liquids is one of the grand challenges of physics. Dynamic heterogeneity, characterized by the propensity of particles, is often used as a proxy for the dynamic slowing down. In this work, we introduce an unsupervised machine learning approach based on a time-lagged autoencoder (TAE) to elucidate the effect of structural features on the long-time dynamic heterogeneity of supercooled liquids. The TAE uses an autoencoder to reconstruct features at time $t + \Delta t$ from input features at time $t$ for individual particles, and the resulting latent space variables are considered as order parameters. In the Kob-Andersen system, with a $\Delta t$ about a thousand times smaller than the relaxation time, the TAE order parameter exhibits a remarkable correlation with the long-time propensity. We find that radial features on all length-scales are required to capture the long-time dynamics, consistent with recent simulations. This shows that fluctuations of structural features contain sufficient information about the long-time dynamic heterogeneity.
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