Perfect Transfer of Entanglement and One-Way Quantum Steering via Parametric Frequency Converter in a Two-mode Cavity Magnomechanical System

Abstract: We study the effects of a parametric frequency converter in a two-mode cavity system where one of the cavity mode is coupled with yttrium iron garnet (YIG) via magnetic dipole interaction. Parametric frequency converter acts as a nonlinear source for enhanced entanglement among all bipartitions and asymmetrical quantum steering. The behavior of the two types of quantum correlations are shown to be dependent on parametric coupling and the associated phase factor. We show that cavity-cavity entanglement and cavity-phonon entanglement (cavity-magnon entanglement) decreases (increases) with the increase of the parametric phase factor {\phi}. In addition, generated entanglements in the present system have shown to be more robust against the thermal effects, with the inclusion of the parametric converter as compared with the bare cavity case. Another intriguing finding is the asymmetric one-way steering, where we notice that magnon and phonon modes can steer the indirectly coupled cavity modes, yet the steering in swapped direction is not observed. It is of great interest that the perfect transfer of entanglement and quantum steering is achieved among different modes by adjusting the system's parameters. In fact, our protocol for these transferring processes suggests a different approach to the processing and storage of quantum information.