A classical theory can capture prethermal DTCs in high-dimensional lattices with short- to long-range interactions in which discrete time translational symmetry is broken up to an exponentially long time scale (in the driving frequency). Credit: © Figure adapted from Pizzi et al. to appear in PRL and PRB 2021.

**An international team of physicists has shown that novel non-equilibrium phases of matter — called prethermal discrete time crystals (DTCs) — can emerge in classical dynamics and do not depend on quantum mechanics. This makes large simulations with relevance to experiments possible.**

DTCs generalize the notion of phase of matter to the non-equilibrium realm. They break the discrete time-translational symmetry of a periodic drive by responding at a subharmonic of that frequency. Among the declinations of time-crystalline phenomena that have been investigated recent years, discrete time-symmetry breaking in prethermal DTCs lasts for a finite but very long time (exponential in drive frequency). Discovered in a quantum-mechanical setting, analyzing prethermal DTCs has so far remained challenging to due to the notorious complexity of quantum many-body systems.

In a double publication, the team of physicists from Cambridge, TU Munich, and Nottingham (now at the University of Vienna) show that prethermal DTCs can be captured by a classical theory that has virtually no numerical limitations. With large-scale numerical simulations, the authors provide the up-to-date clearest portrait of these phenomena, e.g. the first instance of a prethermal DTC with short-range interactions in three dimensions and scenarios of prime relevance for experiments.

These two works establish classical Hamiltonian dynamics as an approach to large-scale simulations of prethermal phases of matter, thereby remove the stringent constraints for quantum many-body simulations, and open new avenues in the growing field of non-equilibrium many-body dynamics.

Reference: “Classical Prethermal Phases of Matter” by Andrea Pizzi, Andreas Nunnenkamp and Johannes Knolle, 27 September 2021, *Physical Review Letters*.

DOI: 10.1103/PhysRevLett.127.140602

Source: SciTechDaily

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