Control of magnon-magnon coupling in Ni80Fe20 nanocross arrays through system dimensions

Abstract

Hybrid magnonics, founded on the coherent interplay between magnons and various quasiparticles, provides avenues for quantum transduction and the seamless transmission of coherent information. Magnon-magnon coupling, which exhibits remarkable coupling strength advantages over light-matter interactions, has emerged as a promising field. This research investigates magnon-magnon coupling in Ni80Fe20 nanocross arrays, with a focus on controlling the anticrossing phenomenon. Through a methodical adjustment of the nanocross arm length, it becomes possible to fine-tune the strength of coupling. The significance of the observed effect becomes evident when examining the power and phase profiles of distinct spin-wave (SW) modes in close proximity to and at a considerable distance from the anticrossing point. The research contributes to bridging the gap in hybrid quasi-particle interactions and offers insights into magnon-magnon coupling control. The findings open avenues for efficient magnon-based technologies and systems enabling efficient control of SW propagation characteristics and coupling, with implications for efficient quantum information processing architectures.