Enhanced entanglement and controlling quantum steering in a Laguerre-Gaussian cavity optomechanical system with two rotating mirrors

Gaussian quantum steering is a type of quantum correlation in which two entangled states exhibit asymmetry. We present an efficient theoretical scheme for controlling quantum steering and enhancing entanglement in a Laguerre-Gaussian (LG) rotating cavity optomechanical system with an optical parametric amplifier (OPA) driven by coherent light. The numerical simulation results show that manipulating system parameters such as parametric gain $\chi$, parametric phase $\theta$, and rotating mirror frequency, among others, significantly improves mirror-mirror and mirror-cavity entanglement. In addition to bipartite entanglement, we achieve mirror-cavity-mirror tripartite entanglement. Another intriguing discovery is the control of quantum steering, for which we obtained several results by investigating it for various system parameters. We show that the steering directivity is primarily determined by the frequency of two rotating mirrors. Furthermore, for two rotating mirrors, quantum steering is found to be asymmetric both one-way and two-way. As a result, we can assert that the current proposal may help in the understanding of non-local correlations and entanglement verification tasks.