Cavity optomechanics enables active manipulation of mechanical resonators through
backaction cooling and amplification. This ability to control mechanical motion with retarded …

The ability to control mechanical motion with optical forces has made it possible to cool
mechanical resonators to their quantum ground states. The same techniques can also be …

Recent experimental progress in cavity optomechanics has allowed cooling of mesoscopic
mechanical oscillators via dynamic backaction provided by the parametric coupling to either …

Dynamical backaction has proven to be a versatile tool in cavity optomechanics, allowing for
precise manipulation of a mechanical resonator's motion using confined optical photons. In …

Cavity opto-mechanics enabled radiation-pressure coupling between optical and
mechanical modes of a micro-mechanical resonator gives rise to dynamical backaction …

Cooling of mesoscopic mechanical resonators represents a primary concern in cavity
optomechanics. In this Letter, in the strong optomechanical coupling regime, we propose to …

The coherent transduction of information between microwave and optical domains is a
fundamental building block for future quantum networks. A promising way to bridge these …

Preparing a massive mechanical resonator in a state with quantum limited motional energy
provides a promising platform for studying fundamental physics with macroscopic systems …

Cavity-enhanced radiation-pressure coupling between optical and mechanical degrees of
freedom allows quantum-limited position measurements and gives rise to dynamical …

An optomechanical microcavity can considerably enhance the interaction between light and
mechanical motion by confining light to a subwavelength volume. However, this comes at …