Reservoir-induced stabilization of a periodically driven classical spin chain: Local versus global relaxation

Floquet theory is an indispensable tool for analyzing periodically driven quantum many-body systems. Although it does not universally extend to classical systems, some of its methodologies can be adopted in the presence of well-separated timescales. Here we use these tools to investigate the stroboscopic behaviors of a classical spin chain that is driven by a periodic magnetic field and coupled to a thermal reservoir. We detail and expand our previous work: we investigate the significance of higher-order corrections to the classical Floquet-Magnus expansion in both the high- and low-frequency regimes; explicitly probe the evolution dynamics of the reservoir; and further explore how the driven system and the reservoir synchronize with the applied field at low frequencies. In line with our earlier results, we find that the high-frequency regime is characterized by a local Floquet-Gibbs ensemble with the reservoir acting as a nearly-reversible heat sink. At low frequencies, the driven system rapidly enters a synchronized state, which can only be fully described in a global picture accounting for the concurrent relaxation of the reservoir in a fictitious magnetic field arising from the drive. We highlight how the evolving nature of the reservoir may still be incorporated in a local picture by introducing an effective temperature. Finally, we show that generic local-dissipation models that account for the influence of the reservoir on the driven system phenomenologically through Markovian dissipative equations of motion can generally not reproduce the rich behavior that our microscopic simulations reveal. In particular, such models prove insufficient to account for the suppression of overall energy absorption that is induced by the here observed synchronization between driven system and reservoir.

Automated summary

Floquet theory is applied to investigate the stroboscopic behaviors of a classical spin chain driven by a periodic magnetic field. The high-frequency mode is described by a local Floquet-Gibbs ensemble, with the thermal reservoir acting as a nearly-reversible heat sink. At low frequencies, the system and the reservoir synchronize and enter a synchronized state, which requires considering the evolution dynamics of the reservoir. Furthermore, generic local-dissipation models fail to reproduce the suppression of overall energy absorption induced by the synchronization between the driven system and the reservoir.