Geometrical shapes effects of optical cavity on entanglement dynamics of optomechanical systems: A numerical analysis

In this work, a model of optomechanical system was investigated by analyzing the entanglement dynamics of two related mechanical oscillators in a modified system. Geometrical shapes effects of optical cavities on entanglement of a representative optomechanical system were investigated by means of performing numerical analysis. It was signified that the steady-state or the dynamic behavior of optomechanical engagement could be created owing to the strength of mechanical pairs, which are strong towards the oscillating temperature. In addition, the mentioned entanglement dynamics were seen to be entirely related to the natural state's stability. Furthermore, rendering the mechanical damping effects, the critical mechanical coupling strength-related analytical expression, where the transition from a steady state to a dynamic clamp occurs, was reported. In the studied system, two identical mechanical oscillators were formed in different conditions of the optical cavities shapes.

Automated summary

In this study, the entanglement dynamics of two related mechanical oscillators in a modified optomechanical system were analyzed to investigate the effects of geometrical shapes of optical cavities on the entanglement of a representative optomechanical system. It was found that the strength of mechanical pairs, which depend on the oscillating temperature, can generate steady-state or dynamic behavior of optomechanical engagement. The entanglement dynamics were also found to be closely related to the stability of the natural state.