Mechanical systems prepared in quantum non-Gaussian states constitute a new advanced
class of phenomena breaking the laws of classical physics. Specifically, such mechanical …

Generating nonclassical states in macroscopic systems is a long-standing challenge. A
promising platform in the context of this quest are novel hybrid systems based on magnetic …

Optomechanical systems in the well-resolved-sideband regime are ideal for studying a
myriad of quantum phenomena with mechanical systems, including backaction-evading …

In this paper, we study static bistability and mechanical cooling of a dissipative
optomechanical cavity filled with a Kerr medium. The system exhibits optical bistability for a …

We show how to prepare magnonic squeezed states in an optomagnomechanical system in
which magnetostriction induced mechanical displacement couples to an optical cavity via …

Quantum optical measurement techniques offer a rich avenue for quantum control of
mechanical oscillators via cavity optomechanics. In particular, a powerful yet little explored …

The ability to prepare a macroscopic mechanical resonator into a quantum superposition
state is an outstanding goal of cavity optomechanics. Here, we propose a technique to …

Micro-and nanoscale optical or microwave cavities are used in a wide range of classical
applications and quantum science experiments, ranging from precision measurements …

We study static behavior and mechanical cooling of a dissipative optomechanical system by
considering a phase-controlled coupling strength. We find that the static displacement of the …

Quantum non-Gaussian states are crucial for the fundamental understanding of non-linear
bosonic systems and simultaneously advanced applications in quantum technologies. In …