Discrete Floquet time crystals (DFTCs) are characterized by the spontaneous breaking of the discrete time-translational invariance characteristic of Floquet-driven systems. In analogy with equilibrium critical points, also time-crystalline phases display critical behavior of different order, i.e., oscillations whose period is a multiple p > 2 of the Floquet driving period. Here, we introduce an experimentally accessible order parameter which is able to unambiguously detect crystalline phases regardless of the value of p and, at the same time, is a useful tool for chaos diagnostic. This p aradigm allows us to investigate the phase diagram of the long-range (LR) kicked Ising model to an unprecedented depth, unveiling a rich landscape characterized by self-similar fractal boundaries. Our theoretical picture describes the emergence of DFTCs phase both as a function of the strength and period of the Floquet drive, capturing the emergent Z(p) symmetry in the Floquet-Bloch waves.
Fractal nature of high-order time crystal phases / Giachetti, Guido; Solfanelli, Andrea; Correale, Lorenzo; Defenu, Nicolò. - In: PHYSICAL REVIEW. B. - ISSN 2469-9950. - 108:14(2023), pp. 1-7. [10.1103/physrevb.108.l140102]
Fractal nature of high-order time crystal phases
Giachetti, Guido;Solfanelli, Andrea;Correale, Lorenzo;Defenu, Nicolò
2023-01-01
Abstract
Discrete Floquet time crystals (DFTCs) are characterized by the spontaneous breaking of the discrete time-translational invariance characteristic of Floquet-driven systems. In analogy with equilibrium critical points, also time-crystalline phases display critical behavior of different order, i.e., oscillations whose period is a multiple p > 2 of the Floquet driving period. Here, we introduce an experimentally accessible order parameter which is able to unambiguously detect crystalline phases regardless of the value of p and, at the same time, is a useful tool for chaos diagnostic. This p aradigm allows us to investigate the phase diagram of the long-range (LR) kicked Ising model to an unprecedented depth, unveiling a rich landscape characterized by self-similar fractal boundaries. Our theoretical picture describes the emergence of DFTCs phase both as a function of the strength and period of the Floquet drive, capturing the emergent Z(p) symmetry in the Floquet-Bloch waves.| File | Dimensione | Formato | |
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