Abstract
In this work, we reported a ubiquitous presence of topological Floquet time crystal (TFTC) in one-dimensional periodically-driven systems. The rigidity and realization of spontaneous discrete time-translation symmetry (DTS) breaking in our model require necessarily coexistence of anomalous topological invariants (0 modes and $\pi$ modes), instead of the presence of disorders or many-body localization. We found that in a particular frequency range of the underlying drive, the anomalous Floquet phase coexistence between zero and pi modes can produce the period-doubling (2T, two cycles of the drive) that breaks the spontaneously, leading to the subharmonic response ($\omega/2$, half the drive frequency). The rigid period-oscillation is topologically-protected against perturbations due to both non-trivially opening of 0 and $\pi$-gaps in the quasienergy spectrum, thus, as a result, can be viewed as a specific "Rabi oscillation" between two Floquet eigenstates with certain quasienergy splitting $\pi/T$. Our modeling of the time-crystalline 'ground state' can be easily realized in experimental platforms such as topological photonics and ultracold fields. Also, our work can bring significant interests to explore topological phase transition in Floquet systems and to bridge the gap between Floquet topological insulators and photonics, and period-doubled time crystals.
Highlights
Spontaneous symmetry breaking plays a profound role in modern physics, leading to a variety of condensed states of matter and fundamental particles
The possibility of the spontaneous timetranslation symmetry breaking in thermal equilibrium was ruled out by a no-go theorem [4,5,6,7], Floquet time crystals that break the discrete time-translation symmetry in periodically driven systems proposed in Refs. [8,9,10,11,12,13,14,15] attracted intense attention
In the driven Su-Schrieffer-Heeger (SSH) model as we studied previously [43], we found that in a specific drive-frequency region where the two topological phases coexist with quasienergy difference given by |επ − ε0| = π /T, the system exhibits a persisting period-2T oscillation which breaks the underlying discrete time-translation symmetry
Summary
Spontaneous symmetry breaking plays a profound role in modern physics, leading to a variety of condensed states of matter and fundamental particles. In the driven Su-Schrieffer-Heeger (SSH) model as we studied previously [43], we found that in a specific drive-frequency region where the two topological phases coexist with quasienergy difference given by |επ − ε0| = π /T , the system exhibits a persisting period-2T oscillation which breaks the underlying discrete time-translation symmetry We dubbed this period-doubling phenomenon “topological Floquet time crystals (TFTCs)," since in our Floquet time-crystalline model, the topological protection inherited from topological phase coexistence instead of many-body interaction and disorders is of the essence to stabilize the long-range subharmonic response (ω/2), and robustness against perturbations [50,51]. Our results suggest an exciting field of studying time crystals in noninteracting topological Floquet systems, which can be implemented in experiments, such as ultracold atoms and topological photonics
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