Squeezed vacuum interaction with an optomechanical cavity containing a quantum well

We investigate a hybrid system consisting of an optomechanical resonator and an optical cavity containing a quantum well. The system is coupled to a squeezed vacuum reservoir. We analyze the effect of the injection of squeezed photons inside the cavity on the intensity spectrum. The system reaches a regime of hybrid resonance where mechanical, excitonic and cavity modes are intermixed. Despite that the optomechanical interaction is the source of the nonlinearity in the system, the optimum squeezing is obtained at the hybrid resonance frequencies. However, when the squeezed vacuum is applied, at these frequencies the minimum squeezing is realized as well as an increase of fluctuations is observed. We show that the squeezed vacuum transforms the coherent states into highly squeezed states of light, and offers a great flexibility to obtain maximal squeezing. Furthermore, a perfect squeezing is predicted.

Automated summary

We investigate a hybrid system consisting of an optomechanical resonator and an optical cavity containing a quantum well. The system is coupled to a squeezed vacuum reservoir. The effect of injection of squeezed photons inside the cavity on the intensity spectrum is analyzed. The system reaches a regime of hybrid resonance where mechanical, excitonic and cavity modes are intermixed. Optimum squeezing is obtained at the hybrid resonance frequencies, despite the optomechanical interaction being the source of nonlinearity in the system. However, when squeezed vacuum is applied, minimal squeezing is realized at these frequencies along with an increase in fluctuations. The squeezed vacuum transforms coherent states into highly squeezed states of light, providing flexibility to achieve maximal squeezing. Furthermore, perfect squeezing is predicted.