Driven dissipative quantum dynamics in a cavity magnon-polariton system

The dynamics of arbitrary-order quantum correlations in a cavity magnon-polariton system are investigated based on the quantum master equation in the coherent state representation. The phenomena of Rabi-like oscillation and level repulsion of the average cavity-photon number agree remarkably well with existing experimental observations. The competing nature of coherent and incoherent components in these two cases is further revealed by the second-order quantum coherence of the cavity photons and magnons, which can be systematically tuned by the driving microwave and thermal bath. Our results demonstrate the rich higher-order quantum dynamics induced by magnetic light-matter interaction and serve as an indispensable step toward exploring nonclassical states for cavity photons and magnons in quantum cavity magnonics.

Automated summary

The dynamics of arbitrary-order quantum correlations in a cavity magnon-polariton system show rich higher-order quantum dynamics, which can be systematically tuned by the driving microwave and thermal bath. This research serves as an indispensable step toward exploring nonclassical states for cavity photons and magnons in quantum cavity magnonics.