Continuous time crystals as a PT symmetric state and the emergence of critical exceptional points

Continuous time-translation symmetry is often spontaneously broken in open quantum systems, and the condition for their emergence has been actively investigated. However, there are only a few cases in which its condition for appearance has been fully elucidated. In this Letter, we show that a Lindladian parity-time (PT) symmetry can generically produce persistent periodic oscillations, including dissipative continuous time crystals, in one-collective spin models. By making an analogy to non-reciprocal phase transitions, we demonstrate that a transition point from the dynamical phase is associated with spontaneous PT symmetry breaking and typically corresponds to a \textit{critical exceptional point}. Interestingly, the periodic orbits in the PT-symmetric phase are found to be center-type, implying an initial-state-dependent amplitude. These results are established by proving that the Lindbladian PT symmetry at the microscopic level implies a non-linear PT symmetry, and by performing a linear stability analysis near the transition point. This research will further our understanding of novel non-equilibrium phases of matter and phase transitions with spontaneous anti-unitary symmetry breaking.