Strong interactions between magnetic materials and electrodynamic cavities mix together
spin and photon properties, producing unique hybridized behavior. The study of such …

We present a theoretical approach to use ferromagnetic or ferrimagnetic nanoparticles as
microwave nanomagnonic cavities to concentrate microwave magnetic fields into deeply …

One pillar of quantum magnonics is the exploration of the utilization of the mediation role of
magnons in different platforms to develop quantum technologies. The efficient coupling …

We experimentally realize circularly polarized unidirectional cavity magnon polaritons in a
torus-shaped microwave cavity loaded by a small magnetic sphere. At special positions, the …

The QCD (Quantum ChromoDynamics) axion emerged as one of the best-motivated dark
matter candidates. In 2018, the Axion Dark Matter eXperiment (ADMX), one of the US …

Magnons have demonstrated enormous potential for the next generation of information
technology and quantum computing. In particular, the coherent state of magnons resulting …

Identifying hidden states in nonlinear physical systems that evade direct experimental
detection is important as disturbances and noises can place the system in a hidden state …

A photon-magnon hybrid system can be realized by coupling the electron spin resonance of
a magnetic material to a microwave cavity mode. The quasiparticles associated with the …

The explosive development of quantum magnonics is associated with the possibility of its
use as macroscopic quantum systems. In particular, they can find an application for quantum …

Scalable quantum information systems would store, manipulate, and transmit quantum
information locally and across a quantum network, but no single qubit technology is currently …