The ability to engineer entangled states that involve macroscopic objects is of particular
importance for a wide variety of quantum‐enabled technologies, ranging from quantum …

Chip-scale multimode optomechanical systems have unique benefits for sensing, metrology,
and quantum technologies relative to their single-mode counterparts. Slot-mode …

Squeezing light in an optomechanical system involves reducing quantum noise in one of the
light's quadratures through the interaction between optical and mechanical modes …

Optomechanical systems produce chaotic behavior due to the nonlinear interaction between
photons and phonons, and the same systems are used to understand the synthetic fields as …

The preparation of mechanical quadrature-squeezed states holds significant importance in
cavity optomechanics because the squeezed states have extensive applications in …

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 focus on the generation and control of simultaneous squeezing for two mechanical
oscillators in a cavity optomechanical system. The two mechanical oscillators couple to an …

We propose an innovative scheme to efficiently prepare strong mechanical squeezing by
utilizing the synergistic mechanism of two-tone driving and parametric pumping in an …

We propose a scheme to enhance optomechanical cooling via synthetic magnetism and
frequency modulation (FM) in a three-mode loop-coupled optomechanical system. By …

Photon‐assisted quantum phase transitions (QPTs) are studied in a cavity optomechanical
system that consists of one optical cavity and two nonlinear mechanical resonators and …