Hybrid magnonics: physics, circuits and applications for coherent information processing

TL;DR

This paper reviews recent advances in hybrid magnonic systems, emphasizing their potential for coherent information processing through tunable magnonic excitations integrated into circuits and devices.

Contribution

It provides a comprehensive overview of the physics, circuit integration, and future applications of magnon-based hybrid systems for coherent information processing.

Findings

Magnons are highly tunable and can couple with various excitations.

Strong coupling enables exploration of coherent dynamics.

Magnonic devices are compatible with microwave circuits and quantum technologies.

Abstract

Hybrid dynamic systems have recently gained interests with respect to both fundamental physics and device applications, particularly with their potential for coherent information processing. In this perspective, we will focus on the recent rapid developments of magnon-based hybrid systems, which seek to combine magnonic excitations with diverse excitations for transformative applications in devices, circuits and information processing. Key to their promising potentials is that magnons are highly tunable excitations and can be easily engineered to couple with various dynamic media and platforms. The capability of reaching strong coupling with many different excitations has positioned magnons well for studying solid-state coherent dynamics and exploiting unique functionality. In addition, with their gigahertz frequency bandwidth and the ease of fabrication and miniaturization, magnonic devices and systems can be conveniently integrated into microwave circuits for mimicking a broad range of device concepts that have been applied in microwave electronics, photonics and quantum information. We will discuss a few potential directions for advancing magnon hybrid systems, including on-chip geometry, novel coherent magnonic functionality, and coherent transduction between different platforms. As future outlook, we will discuss the opportunities and challenges of magnonic hybrid systems for their applications in quantum information and magnonic logic.