Noise analysis of a quasi-phase-matched quantum frequency converter and higher-order counter-propagating SPDC

TL;DR

This paper investigates the noise sources in a quantum frequency converter using a periodically-poled crystal, revealing dominant noise mechanisms and higher-order processes that limit device performance.

Contribution

It provides the first comprehensive analysis of noise spectra in a CW-pumped QFC device, identifying parasitic SPDC and higher-order effects as key limitations.

Findings

Raman scattering dominates noise from 1140 nm to 1330 nm.

Parasitic SPDC is the main noise source beyond 60 THz energy shifts.

Higher-order counter-propagating SPDC processes up to order 44 were observed.

Abstract

Quantum frequency conversion (QFC) will be an indispensable ingredient in future quantum technologies. For example, large-scale fibre-based quantum networks will require QFC to interconnect heterogeneous building blocks like emitters, channels, memories and detectors. The performance of existing QFC devices - typically realised in periodically-poled nonlinear crystals - is often severely limited by parasitic noise that arises when the pump wavelength lies between the inter-converted wavelengths. Here we comprehensively investigate the noise spectrum of a QFC device pumped by a CW 1064 nm laser. The converter was realised as a bulk periodically-poled potassium titanyl phosphate (ppKTP) crystal quasi-phase-matched for conversion between 637 nm and 1587 nm, which was also polished and coated to resonantly enhance the pump field by a factor of 50. While Raman scattering dominates the noise background from 1140 nm to 1330 nm, at larger energy shifts (beyond 60 THz), parasitic spontaneous parametric down-conversion (SPDC) is the strongest noise source. Further, the noise spectrum was contaminated by a regular succession of narrow-band peaks, which we attribute to a heretofore unidentified higher-order counter-propagating SPDC processes - with quasi-phase-matching orders up to 44 evident in our measurements. This work provides a comprehensive overview of the limiting noise sources in QFC devices that use quasi-phase-matched crystals and will prove an invaluable resource in guiding their future development.