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Main Authors: Mann, Felix, Chrzanowski, Helen M., Gewers, Felipe, Placke, Marlon, Ramelow, Sven
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2407.03845
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author Mann, Felix
Chrzanowski, Helen M.
Gewers, Felipe
Placke, Marlon
Ramelow, Sven
author_facet Mann, Felix
Chrzanowski, Helen M.
Gewers, Felipe
Placke, Marlon
Ramelow, Sven
contents 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.
format Preprint
id arxiv_https___arxiv_org_abs_2407_03845
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Noise analysis of a quasi-phase-matched quantum frequency converter and higher-order counter-propagating SPDC
Mann, Felix
Chrzanowski, Helen M.
Gewers, Felipe
Placke, Marlon
Ramelow, Sven
Quantum Physics
Optics
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.
title Noise analysis of a quasi-phase-matched quantum frequency converter and higher-order counter-propagating SPDC
topic Quantum Physics
Optics
url https://arxiv.org/abs/2407.03845