Tunable Strong Magnon-Magnon Coupling in Two-Dimensional Array of Diamond Shaped Ferromagnetic Nanodots

TL;DR

This paper demonstrates tunable strong magnon-magnon coupling in a two-dimensional array of ferromagnetic nanodots, with potential applications in quantum magnonics and on-chip hybrid systems.

Contribution

It shows that intermodal magnon coupling in nanodots can reach strong coupling regime and be externally tuned via magnetic field adjustments.

Findings

Coupling strength up to 0.82 GHz achieved

Intermodal coupling mediated by exchange field

Coupling tunable by bias field strength and orientation

Abstract

Hybrid magnonics involving coupling between magnons and different quantum particles have been extensively studied during past few years for varied interests including quantum electrodynamics. In such systems, magnons in magnetic materials with high spin density are utilized where the coupling strength is collectively enhanced by the square root of the number of spins to overcome the weaker coupling between individual spins and the microwave field. However, achievement of strong magnon-magnon coupling in a confined nanomagnets would be essential for on-chip integration of such hybrid systems. Here, through intensive study of interaction between different magnon modes in a Ni80Fe20 (Py) nanodot array, we demonstrate that the intermodal coupling can approach the strong coupling regime with coupling strength up to 0.82 GHz and cooperativity of 2.51. Micromagnetic simulations reveal that the intermodal coupling is mediated by the exchange field inside each nanodot. The coupling strength could be continuously tuned by varying the bias field strength and orientation, opening routes for external control over hybrid magnonic systems. These findings could greatly enrich the rapidly evolving field of quantum magnonics.