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Time crystallinity in open quantum systems

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arxiv 1908.11339 v4 pith:MWSDGOL6 submitted 2019-08-29 quant-ph

Time crystallinity in open quantum systems

classification quant-ph
keywords timeopensystemscrystalsclosedcrystalnon-equilibriumquantum
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Time crystals are genuinely non-equilibrium quantum phases of matter that break time-translational symmetry. While in non-equilibrium closed systems time crystals have been experimentally realized, it remains an open question whether or not such a phase survives when systems are coupled to an environment. Although dissipation caused by the coupling to a bath may stabilize time crystals in some regimes, the introduction of incoherent noise may also destroy the time crystalline order. Therefore, the mechanisms that stabilize a time crystal in open and closed systems are not necessarily the same. Here, we propose a way to identify an open system time crystal based on a single object: the Floquet propagator. Armed with such a description we show time-crystalline behavior in an explicitly short-range interacting open system and demonstrate the crucial role of the nature of the decay processes.

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