Interplay between an absorbing phase transition and synchronization in a driven granular system

Absorbing phase transitions (APTs) are widespread in non-equilibrium systems, spanning condensed matter, epidemics, earthquakes, ecology, and chemical reactions. APTs feature an absorbing state in which the system becomes entrapped, along with a transition, either continuous or discontinuous, to an...

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Bibliographic Details
Published inarXiv.org
Main Authors Maire, R, Plati, A, Stockinger, M, Trizac, E, Smallenburg, F, Foffi, G
Format Paper
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 23.01.2024
Subjects
Chemical reactions
Phase transitions
Statistical mechanics
Synchronism
Vertical motion
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Summary:Absorbing phase transitions (APTs) are widespread in non-equilibrium systems, spanning condensed matter, epidemics, earthquakes, ecology, and chemical reactions. APTs feature an absorbing state in which the system becomes entrapped, along with a transition, either continuous or discontinuous, to an active state. Understanding which physical mechanisms determine the order of these transitions represents a challenging open problem in non-equilibrium statistical mechanics. Here, by numerical simulations and mean-field analysis, we show that a quasi-2d vibrofluidized granular system exhibits a novel form of APT. The absorbing phase is observed in the horizontal dynamics below a critical packing fraction, and can be continuous or discontinuous based on the emergent degree of synchronization in the vertical motion. Our results provide a direct representation of a feasible experimental scenario, showcasing a surprising interplay between dynamic phase transition and synchronization.
ISSN:2331-8422