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 …

The nonreciprocal propagation of light typically requires use of materials like ferrites or
magneto-optical media with a strong magnetic bias or methods based on material …

We study the controllable output field generation from a cavity magnomechanical resonator
system that consists of two coupled microwave resonators. The first cavity interacts with a …

Finding new strategies for the generation and preservation of quantum resources, eg
entanglement between spatially separated macroscopic systems enables reliable and fertile …

Long-distance strong coupling between short-wavelength magnons remains an outstanding
challenge in quantum magnonics, an emerging interdiscipline between magnonics and …

The interaction between microwave photons and magnons is well understood and
originates from the Zeeman coupling between spins and a magnetic field. Interestingly, the …

Nonlinear systems possess complex dynamic behaviors and transition characteristics
among various states, which make the behaviors of nonlinear systems hard to predict and …

Cavity magnonics, which studies the interaction of light with magnetic systems in a cavity, is
a promising platform for quantum transducers and quantum memories. At microwave …

We demonstrate the influence of damping and field-like torques in the magnon–photon
coupling process by classically integrating the generalized Landau–Lifshitz–Gilbert …

Coupling of space-separated resonators is interesting for quantum and communication
technologies. In this work, we show that antiferromagnetic resonance in separated parallel …