非平衡态热力学
相变
同步(交流)
统计物理学
相位同步
活性物质
物理
相(物质)
代表(政治)
粒状材料
软物质
国家(计算机科学)
计算机科学
凝聚态物理
拓扑(电路)
热力学
量子力学
数学
化学
物理化学
政治
政治学
生物
算法
胶体
组合数学
法学
细胞生物学
作者
R. Maire,Andrea Plati,M. Stockinger,Emmanuel Trizac,Frank Smallenburg,Giuseppe Foffi
标识
DOI:10.1103/physrevlett.132.238202
摘要
Absorbing phase transitions (APTs) are widespread in nonequilibrium 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 nonequilibrium 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.
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