English

Magnon-photon strong coupling for tunable microwave circulators

Applied Physics 2020-05-06 v2 Quantum Physics

Abstract

We present a generic theoretical framework to describe non-reciprocal microwave circulation in a multimode cavity magnonic system and assess the optimal performance of practical circulator devices. We show that high isolation (> 56 dB), extremely low insertion loss (< 0.05 dB), and flexible bandwidth control can be potentially realized in high-quality-factor superconducting cavity based magnonic platforms. These circulation characteristics are analyzed with materials of different spin densities. For high-spin-density materials such as yttrium iron garnet, strong coupling operation regime can be harnessed to obtain a broader circulation bandwidth. We also provide practical design principles for a highly integratible low-spin-density material (vanadium tetracyanoethylene) for narrow-band circulator operation, which could benefit noise-sensitive quantum microwave measurements. This theory can be extended to other coupled systems and provide design guidelines for achieving tunable microwave non-reciprocity for both classical and quantum applications.

Keywords

Cite

@article{arxiv.1912.07128,
  title  = {Magnon-photon strong coupling for tunable microwave circulators},
  author = {Na Zhu and Xu Han and Chang-Ling Zou and Mingrui Xu and Hong X. Tang},
  journal= {arXiv preprint arXiv:1912.07128},
  year   = {2020}
}
R2 v1 2026-06-23T12:46:33.844Z