A Robust Large-Period Discrete Time Crystal and its Signature in a Digital Quantum Computer

Abstract: Discrete time crystals (DTCs) are novel out-of-equilibrium quantum states of matter which break time translational symmetry. So far, only the simplest form of DTCs that exhibit period-doubling dynamics has been unambiguously realized in experiments. We develop an intuitive interacting spin-$1/2$ system that supports the more non-trivial period-quadrupling DTCs ($4T$-DTCs) and demonstrate its digital simulation on a noisy quantum processor. Remarkably, we found a strong signature of the predicted $4T$-DTC that is robust against and, in some cases, amplified by different types of disorders. Our findings thus shed light on the interplay between disorder and quantum interactions on the formation of time crystallinity beyond periodic-doubling, as well as demonstrate the potential of existing noisy intermediate-scale quantum devices for simulating exotic non-equilibrium quantum states of matter.