Multi-path vector entanglement engineering via dark mode control in optomechanics

TL;DR

This paper introduces a novel method to generate multi-path entanglement in an optomechanical system by controlling dark modes through polarization and mechanical coupling, enhancing noise resilience for quantum applications.

Contribution

It presents a new scheme utilizing dark mode control via polarization and mechanical coupling to engineer multi-path bipartite and tripartite entanglements in optomechanics.

Findings

Dark mode breaking enables multi-path entanglement generation.

Entanglements are more robust against thermal noise in the dark mode breaking regime.

The scheme can produce degenerate twin entangled states for quantum information tasks.

Abstract

We propose a scheme to generate multi-paths entanglement in an optomechanical system by exploiting polarized electromagnetic fields and dark mode control. Our system consists of two mechanically coupled mechanical resonators, which are driven by a common electromagnetic field. An inclusion of a polarizer induces linear polarizations of the electromgnetic field corresponding to the vertical (transverse electric ($\rm{TE}$) and horizontal (transverse magnetic [($\rm{TM}$]) modes, which drive the mechanical resonators. Without the mechanical coupling $J_m=0$, the polarization angle ($\phi$) controls dark mode in the system. The breaking of this dark mode leads to multi-paths engineering of bipartite optomechanical entanglements. By switching on the phonon hopping rate ($J_m\neq0$), both the polarization angle and the modulation phase of the mechanical coupling allow a further control of the dark mode. The simultaneous Dark Mode Breaking (\rm{DMB}) conditions under these two parameters leads to multi-paths bipartite and tripartite entanglements. For a fine tuning of the polarization angle ($\phi=\pi/4$) this scheme enables a generation of twin entangled states, where the bipartite/tripartite generated entangled states are degenerated and might be of great interest for quantum information processing, quantum communication and diverse quantum computational tasks. The generated entanglements are more resilient against thermal fluctuations in the \rm{DMB} regime, i.e., up to two order of magnitude robust than in the Unbreaking regime. Our work sheets light on new possibilities to generate noise-tolerant quantum resources that are useful for plethora of modern quantum technologies.