User Manual Privacy Policy Disclaimer Contact us
  Advanced SearchBrowse





Interference effects in hybrid cavity optomechanics


Cernotik,  Ondrej
Genes Research Group, Research Groups, Max Planck Institute for the Science of Light, Max Planck Society;


Genes,  Claudiu
Genes Research Group, Research Groups, Max Planck Institute for the Science of Light, Max Planck Society;

There are no locators available
Fulltext (public)

(Preprint), 2MB

Supplementary Material (public)
There is no public supplementary material available

Cernotik, O., Genes, C., & Dantan, A. (2018). Interference effects in hybrid cavity optomechanics. arXiv 1809.01420.

Cite as: http://hdl.handle.net/21.11116/0000-0002-1879-C
Radiation pressure forces in cavity optomechanics allow for efficient cooling of vibrational modes of macroscopic mechanical resonators, the manipulation of their quantum states, as well as generation of optomechanical entanglement. The standard mechanism relies on the cavity photons directly modifying the state of the mechanical resonator. Hybrid cavity optomechanics provides an alternative approach by coupling mechanical objects to quantum emitters, either directly or indirectly via the common interaction with a cavity field mode. While many approaches exist, they typically share a simple effective description in terms of a single force acting on the mechanical resonator. More generally, one can study the interplay between various forces acting on the mechanical resonator in such hybrid mechanical devices. This interplay can lead to interference effects that may, for instance, improve cooling of the mechanical motion or lead to generation of entanglement between various parts of the hybrid device. Here, we provide such an example of a hybrid optomechanical system where an ensemble of quantum emitters is embedded into the mechanical resonator formed by a vibrating membrane. The interference between the radiation pressure force and the mechanically modulated Tavis–Cummings interaction leads to enhanced cooling dynamics in regimes in which neither force is efficient by itself. Our results pave the way towards engineering novel optomechanical interactions in hybrid optomechanical systems.