Macroscopic distant magnon modes entanglement via a squeezed drive

Abstract

The generation of robust entanglement in quantum system arrays is a crucial aspect of realizing efficient quantum information processing. Recently, the field of quantum magnonics has garnered significant attention as a promising platform for advancing in this direction. In our proposed scheme, we utilize a one-dimensional array of coupled cavities, with each cavity housing a single yttrium iron garnet (YIG) sphere coupled to the cavity mode through magnetic dipole interaction. To induce entanglement between YIGs, we employ a squeezed vacuum drive, providing the necessary nonlinearity. Our results demonstrate the successful generation of bipartite and tripartite entanglement between distant magnon modes across the entire array, all achieved through a single control drive. Furthermore, the steady-state entanglement between magnon modes is robust against magnon dissipation rates and environment temperature. Our results may find applications of cavity-magnon arrays in quantum information processing and quantum communication systems.