Phase-selective tripartite entanglement and asymmetric Einstein-Podolsky-Rosen steering in squeezed optomechanics

TL;DR

This paper presents a theoretical approach to generate and control phase-selective tripartite entanglement and asymmetric EPR steering in a nonlinear optomechanical system using squeezing-phase-controlled noise flows, advancing quantum resource engineering.

Contribution

It introduces a novel method employing squeezing-phase-controlled noise flows to manipulate entanglement and EPR steering asymmetry in a $ ext{chi}^{(2)}$ WGM resonator, enabling tailored quantum correlations.

Findings

Phase-dependent bipartite and tripartite entanglement can be generated.

Asymmetric EPR steering can be tuned from no-way to two-way regimes.

The method offers flexible control over quantum noise flows for quantum information applications.

Abstract

The generation and manipulation of multipartite entanglement and EPR steering in macroscopic systems not only play a fundamental role in exploring the nature of quantum mechanics, but are also at the core of current developments of various nascent quantum technologies. Here we report a theoretical method using squeezing-phase-controlled quantum noise flows to selectively generate and manipulate quantum entanglement and asymmetric EPR steering in a nonlinear $\chi^{(2)}$ whispering-gallery-mode (WGM) optomechanical resonator. We show that by pumping the $\chi^{(2)}$ nonlinear medium with two-photon optical fields and broadband squeezed lights, a pair of counterpropagating squeezed optical modes could be introduced to the WGM resonator, each coupled with an independent squeezed vacuum reservoir. This configuration could enable squeezing-phase-controlled light-reservoir interaction for each squeezed optical mode, providing a flexible tool for tailoring asymmetric optical noise flows in the counterpropagating modes. Based on this unique feature, it is found that with the injection of asymmetric noise flows, the generation of various types of bipartite and tripartite entanglement become phase-dependent and thus they can be produced in an asymmetric way. More excitingly, it is also found that by further properly adjusting the squeezing parameters, the overall asymmetry of EPR steering can also be stepwise driven from no-way regime, one-way regime to two-way regime. These findings, holding promise for preparing rich types of entangled quantum resources with asymmetric features, may have potential applications in the area of secure quantum information processing such as quantum secure direct communication and one-way quantum computing.