Quantum Network with Magnonic and Mechanical Nodes

A quantum network consisting of magnonic and mechanical nodes connected by light is proposed. Recent years have witnessed a significant development in cavity magnonics based on collective spin excitations in ferrimagnetic crystals, such as yttrium iron garnet (YIG). Magnonic systems are considered to be a promising building block for a future quantum network. However, a major limitation of the system is that the coherence time of the magnon excitations is limited by their intrinsic loss (typically in the order of 1 mu s for YIG). Here, we show that by coupling the magnonic system to a mechanical system using optical pulses, an arbitrary magnonic state (either classical or quantum) can be transferred to and stored in a distant long-lived mechanical resonator. The fidelity depends on the pulse parameters and the transmission loss. We further show that the magnonic and mechanical nodes can be prepared in a macroscopic entangled state. These demonstrate the quantum state transfer and entanglement distribution in such a novel quantum network of magnonic and mechanical nodes. Our work shows the possibility to connect two separate fields of optomagnonics and optomechanics, and to build a long-distance quantum network based on magnonic and mechanical systems.

Automated summary

The study proposes a quantum network consisting of magnonic and mechanical nodes connected by light. It demonstrates the transfer of magnonic states to and storage in distant mechanical resonators using optical pulses, as well as the preparation of magnonic and mechanical nodes in macroscopic entangled states. This work shows the potential to connect optomagnonics and optomechanics fields and build a long-distance quantum network based on magnonic and mechanical systems.