Discrete Time Crystal in quantum Sherrington-Kirkpatrick model
Abstract
Discrete time crystals (DTC) have emerged as significant phase of matter for out-of-equilibrium many-body systems in recent years. Here, we study the role of long-range interactions and disorder in stabilizing the DTC phase. Generally, it is believed that a stable DTC phase can be realized in disordered systems with short-range interactions. We study the periodically driven quantum Sherrington-Kirkpatrick (SK) model of Ising spin-glass in which all spins are coupled to each other with random couplings. We explore the possibility of DTC phase within three different driving protocols. For all the cases, quantum SK model shows a robust DTC phase with no initial state dependence at all. We compare the periodically driven SK model with other models of long-range interactions with uniform coefficients where randomness is induced through a local field. In complete contrast to the SK model, these models show strong initial state dependence with a large number of initial states showing decay in periodic oscillations in spin-spin correlation function with time.