Implementation of One-Way Quantum Steering and Controlled Generation of Asymmetric Tripartite Entanglement in Double Coupling Cavity-Magnonics Subsystems

Two cavity-magnon subsystems coupled via the two single-mode cavities mediated by a non-degenerate parametric down conversion and each cavity carrying a magnon confined in a Yttrium-iron-garnet sphere is proposed to study one-way quantum steering and asymmetric tripartite entanglement. The entanglement can be transferred from the two microwave cavities to the two separated magnon modes using magnetic dipole interaction. Different from previous schemes, the present study demonstrates efficient realization of controllable one-way quantum steering between two magnon modes through asymmetric frequency detunings of the two magnon modes. In addition, an asymmetric tripartite entanglement can also be achieved. Furthermore, the system exhibits robustness to temperatures up to 100 mK, providing a promising avenue for utilizing cavity magnonics systems in unidirectional transmission of quantum information. Two cavity-magnon subsystems coupled via the two single-mode cavities mediated by a non-degenerate JPA and each cavity carrying a magnon confined in a YIG sphere is proposed to study controllable one-way steering and asymmetric tripartite entanglement through asymmetric frequency detunings of two magnon modes. The present proposal may exhibit robustness to temperatures up to 100 mK. image