📝 SummarXiv

Abstract

Boundary time crystals are a class of exotic dissipative quantum phases that spontaneously break continuous time-translation symmetry in the thermodynamic limit of open quantum systems. In finite-size systems, the long-time evolution of boundary time crystals exhibits decaying oscillations that cannot be captured by widely used mean-field theory. To address this issue, we develop an effective approach called the stroboscopic rotating wave approximation, which provides a well approximate state for the long-time evolution of boundary time crystals under strong driving. In this approach, the order parameter exhibits both a long-time decaying envelope governed by an effective Lindblad superoperator and short-time oscillations dominated by a reduced quantum dynamical semigroup. Our results reveal that the competition among dephasing processes along three distinct directions induces persistent oscillations, marking the emergence of the boundary time crystal phase. We obtain the analytical expressions for the steady-state density operator, the oscillation period, and the decay rate of the order parameter in the regime where the coherent energy splitting exceeds the dissipation rate. Our work provides a beyond-mean-field theoretical tool for studying the dynamics of periodically driven open quantum systems and understanding the formation of time crystals.