J. E. Ramírez-Muñoz, J. P. Restrepo Cuartas, H. Vinck-Posada
Published 2018-07-05Version 1
Achieving quantum correlations between two distant systems is a desirable feature for quantum networking. In this work, we study a system composed of two quantum emitter-cavity subsystems spatially separated. A mechanical resonator couples to either both quantum emitters or both cavities leading to quantum correlations between both subsystems such as non-local light-matter dressed states and cavity-cavity normal mode splitting. These indirect couplings can be explained by an effective Hamiltonian for large energy detuning between the mechanical resonator and the atoms/cavities. Moreover, it is found optimal conditions for the physical parameters of the system in order to maximize the entanglement of such phonon-mediated couplings.
Quantum correlations of confined exciton-polaritons
Back-action evasion and squeezing of a mechanical resonator using a cavity detector
Interplay between polarization and quantum correlations of confined polaritons
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