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Higher-order and fractional discrete time crystals in clean long-range interacting systems

Andrea Pizzi, Johannes Knolle, Andreas Nunnenkamp

2021Nature Communications86 citationsDOIOpen Access PDF

Abstract

Discrete time crystals are periodically driven systems characterized by a response with periodicity nT, with T the period of the drive and n > 1. Typically, n is an integer and bounded from above by the dimension of the local (or single particle) Hilbert space, the most prominent example being spin-1/2 systems with n restricted to 2. Here, we show that a clean spin-1/2 system in the presence of long-range interactions and transverse field can sustain a huge variety of different 'higher-order' discrete time crystals with integer and, surprisingly, even fractional n > 2. We characterize these (arguably prethermal) non-equilibrium phases of matter thoroughly using a combination of exact diagonalization, semiclassical methods, and spin-wave approximations, which enable us to establish their stability in the presence of competing long- and short-range interactions. Remarkably, these phases emerge in a model with continous driving and time-independent interactions, convenient for experimental implementations with ultracold atoms or trapped ions.

Topics & Concepts

Semiclassical physicsInteger (computer science)Bounded functionPhysicsRange (aeronautics)Dimension (graph theory)Order (exchange)Spin (aerodynamics)Discrete time and continuous timeHalf-integerHilbert spaceStatistical physicsQuantum mechanicsMathematicsMathematical analysisComputer scienceCombinatoricsMaterials scienceQuantumThermodynamicsStatisticsProgramming languageEconomicsComposite materialFinanceQuantum many-body systemsCold Atom Physics and Bose-Einstein CondensatesOpinion Dynamics and Social Influence
Higher-order and fractional discrete time crystals in clean long-range interacting systems | Litcius