Atomic-scale on-demand photon polarization manipulation with high-efficiency for integrated photonic chips

TL;DR

This paper proposes an atomic-scale, high-efficiency polarization converter for single photons in integrated photonic chips, enabling arbitrary polarization manipulation with tunable frequency and excellent anti-dissipation properties.

Contribution

It introduces a novel scheme integrating a three-level quantum emitter with waveguide modes for on-demand polarization control in quantum photonic circuits.

Findings

Achieves arbitrary polarization conversion for any input polarization.

Provides tunable working frequency and high conversion efficiency.

Demonstrates atomic-scale size and excellent anti-dissipation ability.

Abstract

In order to overcome the challenge of lacking polarization encoding in integrated quantum photonic circuits, we propose a scheme to realize arbitrary polarization manipulation of a single photon by integrating a single quantum emitter in a photonic waveguide. In our scheme, one transition path of the three-level emitter is designed to simultaneously couples with two orthogonal polarization degenerate modes in the waveguide with adjustable coupling strengths, and the other transition path of the three-level emitter is driven by an external coherent field. The proposed polarization converter has several advantages, including arbitrary polarization conversion for any input polarization, tunable working frequency, excellent anti-dissipation ability with high conversion efficiency, and atomic-scale size. Our work provides an effective solution to enable the polarization encoding of photons which can be applied in the integrated quantum photonic circuits, and will boost quantum photonic chip.