Efficient and low-noise single-photon-level frequency conversion interfaces using silicon nanophotonics

TL;DR

This paper demonstrates efficient, low-noise quantum-compatible frequency conversion using silicon nanophotonics, achieving high efficiency and bandwidth with minimal pump power, suitable for single-photon quantum applications.

Contribution

It introduces a compact silicon nitride microring resonator platform for versatile, low-noise frequency conversion with high efficiency, advancing integrated quantum photonics.

Findings

Conversion efficiencies up to 60%+

Bandwidth > 1 GHz

Low pump power (< 60 mW) required

Abstract

Optical frequency conversion has applications ranging from tunable light sources to telecommunications-band interfaces for quantum information science. Here, we demonstrate efficient, low-noise frequency conversion on a nanophotonic chip through four-wave-mixing Bragg scattering in compact (footprint < 0.5 x 10^-4 cm^2) Si3N4 microring resonators. We investigate three frequency conversion configurations: (1) spectral translation over a few nanometers within the 980 nm band, (2) upconversion from 1550 nm to 980 nm, and (3) downconversion from 980 nm to 1550 nm. With conversion efficiencies ranging from 25 % for the first process to > 60 % for the last two processes, a signal conversion bandwidth > 1 GHz, < 60 mW of continuous-wave pump power needed, and background noise levels between a few fW and a few pW, these devices are suitable for quantum frequency conversion of single photon states from InAs quantum dots. Simulations based on coupled mode equations and the Lugiato-Lefever equation are used to model device performance, and show quantitative agreement with measurements.