Variable electro-optic shearing interferometry for ultrafast single-photon-level pulse characterization

Stanislaw Kurzyna; Marcin Jastrzebski; Nicolas Fabre; Wojciech Wasilewski; Michal Lipka; Michal Parniak

doi:10.1364/OE.471108

Variable electro-optic shearing interferometry for ultrafast single-photon-level pulse characterization

Stanislaw Kurzyna, Marcin Jastrzebski, Nicolas Fabre, Wojciech Wasilewski, Michal Lipka, Michal Parniak^*

^*Corresponding author af dette arbejde

Kvanteoptik

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

8 Citationer (Scopus)

14 Downloads (Pure)

Abstract

Despite the multitude of available methods, the characterization of ultrafast pulses remains a challenging endeavor, especially at the single-photon level. We introduce a pulse characterization scheme that maps the magnitude of its short-time Fourier transform. Contrary to many well-known solutions it does not require nonlinear effects and is therefore suitable for single-photon-level measurements. Our method is based on introducing a series of controlled time and frequency shifts, where the latter is performed via an electro-optic modulator allowing a fully-electronic experimental control. We characterized the full spectral and temporal width of a classical and single-photon-level pulse and successfully tested the applicability of the reconstruction algorithm of the spectral phase and amplitude. The method can be extended by implementing a phase-sensitive measurement and is naturally well-suited to partially-incoherent light.

Originalsprog	Engelsk
Tidsskrift	Optics Express
Vol/bind	30
Udgave nummer	22
Sider (fra-til)	39826-39839
Antal sider	14
ISSN	1094-4087
DOI	https://doi.org/10.1364/OE.471108
Status	Udgivet - 24 okt. 2022

Adgang til dokumentet

10.1364/OE.471108Licens: CC BY

oe-30-22-39826Forlagets udgivne version, 3,3 MBLicens: CC BY

Citationsformater

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abstract = "Despite the multitude of available methods, the characterization of ultrafast pulses remains a challenging endeavor, especially at the single-photon level. We introduce a pulse characterization scheme that maps the magnitude of its short-time Fourier transform. Contrary to many well-known solutions it does not require nonlinear effects and is therefore suitable for single-photon-level measurements. Our method is based on introducing a series of controlled time and frequency shifts, where the latter is performed via an electro-optic modulator allowing a fully-electronic experimental control. We characterized the full spectral and temporal width of a classical and single-photon-level pulse and successfully tested the applicability of the reconstruction algorithm of the spectral phase and amplitude. The method can be extended by implementing a phase-sensitive measurement and is naturally well-suited to partially-incoherent light.",

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T1 - Variable electro-optic shearing interferometry for ultrafast single-photon-level pulse characterization

AU - Kurzyna, Stanislaw

AU - Jastrzebski, Marcin

AU - Fabre, Nicolas

AU - Wasilewski, Wojciech

AU - Lipka, Michal

AU - Parniak, Michal

PY - 2022/10/24

Y1 - 2022/10/24

N2 - Despite the multitude of available methods, the characterization of ultrafast pulses remains a challenging endeavor, especially at the single-photon level. We introduce a pulse characterization scheme that maps the magnitude of its short-time Fourier transform. Contrary to many well-known solutions it does not require nonlinear effects and is therefore suitable for single-photon-level measurements. Our method is based on introducing a series of controlled time and frequency shifts, where the latter is performed via an electro-optic modulator allowing a fully-electronic experimental control. We characterized the full spectral and temporal width of a classical and single-photon-level pulse and successfully tested the applicability of the reconstruction algorithm of the spectral phase and amplitude. The method can be extended by implementing a phase-sensitive measurement and is naturally well-suited to partially-incoherent light.

AB - Despite the multitude of available methods, the characterization of ultrafast pulses remains a challenging endeavor, especially at the single-photon level. We introduce a pulse characterization scheme that maps the magnitude of its short-time Fourier transform. Contrary to many well-known solutions it does not require nonlinear effects and is therefore suitable for single-photon-level measurements. Our method is based on introducing a series of controlled time and frequency shifts, where the latter is performed via an electro-optic modulator allowing a fully-electronic experimental control. We characterized the full spectral and temporal width of a classical and single-photon-level pulse and successfully tested the applicability of the reconstruction algorithm of the spectral phase and amplitude. The method can be extended by implementing a phase-sensitive measurement and is naturally well-suited to partially-incoherent light.

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KW - FREQUENCY

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