Single-mode input squeezing and tripartite entanglement in three-mode ponderomotive optomechanics simulations

TL;DR

This paper proposes a scheme to enhance quantum entanglement in optomechanical systems by injecting two single-mode squeezed light fields, demonstrating significant improvements over previous methods through numerical simulations.

Contribution

The study introduces a novel approach using squeezed light inputs to substantially increase bipartite and tripartite entanglement in three-mode ponderomotive optomechanics.

Findings

Maximum bipartite entanglement increased by a factor of 6

Quantum noise of output light is significantly increased

Tripartite entanglement occurs at specific squeezing angles

Abstract

Quantum entanglement is a crucial resource for a wide variety of quantum technologies. However, the current state-of-art methods to generate quantum entanglement in optomechanical systems are not as efficient as all-optical methods utilizing nonlinear crystals. This article proposes a new scheme in which two single-mode squeezed light fields are injected into an optomechanical cavity. We demonstrate through our numerical simulations that the quantum entanglement can be substantially enhanced with the careful selection of squeezing strength and squeezing angle of the two quadrature squeezed light fields. Our results represent a significant improvement in output bipartite photon-photon entanglement over the previously demonstrated schemes using two coherent light fields as inputs. These simulations predict a maximum increase in bipartite optical entanglement by a factor of about 6, as well as increases in the quantum noise of the output light. A perceived loss of quantum information at certain squeezing angles is attributed to tripartite entanglement between the two optical fields and the optomechanical oscillator (OMO). At particular squeezing angles, the bipartite (or tripartite) entanglement can be increased, thus introducing a method of optically controlling the intracavity entanglement. These mechanics can benefit various optical quantum technologies utilizing optomechanical entanglement and continuous variable quantum optics.