Reduction of nonclassical fluctuations by entangled nonidentical emitters in nanophotonic environments

TL;DR

This paper presents a hybrid nanophotonic scheme that generates and detects entanglement and squeezed light from nonidentical quantum emitters, overcoming limitations of traditional methods and enhancing robustness against decoherence.

Contribution

It introduces a broadband nanostructure approach enabling entanglement and squeezing in far-detuned emitters, with improved detection and environmental robustness.

Findings

Nonclassical fluctuations can be used to detect entanglement.

Near-field enhancement allows nonclassical effects outside narrow bands.

The scheme overcomes limitations of noninteracting emitters and is more decoherence-resistant.

Abstract

We propose a scheme in which broadband nanostructures allow to generate squeezed light and entanglement of quantum emitters that are extremely far detuned. It is shown that the reduced fluctuations of the electromagnetic field arising from collective resonance fluorescence provide also a means to detect the entanglement between the emitters. Due to the near-field enhancement in the proposed hybrid systems, these nonclassical effects can be encountered outside both the extremely close separations limiting the observation in free space and narrow frequency bands in high-Q cavities. Our approach permits to overcome the limitations of noninteracting single emitters and is more robust against phase decoherence induced by the environment.