Ultrasensitive Dispersive Fourier Transform Technique for Nonlinear Instability Characterization

Research output: Non-textual formAudiovisual publicationResearch

Authors

  • Lynn Sader
  • Surajit Bose
  • Anahita Khodadad Kashi
  • Yassin Boussafa
  • Romain Dauliat
  • Philippe Roy
  • Marc Fabert
  • Alessandro Tonello
  • Vincent Couderc
  • Michael Kues
  • Benjamin Wetzel
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Details

Original languageEnglish
Media of outputOnline
Publication statusPublished - 2022
EventFrontiers in Optics, FiO 2022 - Rochester, United States
Duration: 17 Oct 202220 Oct 2022

Abstract

We demonstrate the characterization of nonlinear noise-driven dynamics with ultrahigh sensitivity, resolution, and a theoretically unlimited dynamic range using a novel approach of dispersive Fourier transform-based measurements and multiple single photon detectors.

ASJC Scopus subject areas

Cite this

Ultrasensitive Dispersive Fourier Transform Technique for Nonlinear Instability Characterization. Sader, Lynn (Author); Bose, Surajit (Author); Kashi, Anahita Khodadad (Author) et al.. 2022. Event: Frontiers in Optics, FiO 2022, Rochester, United States.

Research output: Non-textual formAudiovisual publicationResearch

Sader, L, Bose, S, Kashi, AK, Boussafa, Y, Dauliat, R, Roy, P, Fabert, M, Tonello, A, Couderc, V, Kues, M & Wetzel, B, Ultrasensitive Dispersive Fourier Transform Technique for Nonlinear Instability Characterization, 2022, Audiovisual publication. https://doi.org/10.1364/FIO.2022.FTu1B.3
Sader, L., Bose, S., Kashi, A. K., Boussafa, Y., Dauliat, R., Roy, P., Fabert, M., Tonello, A., Couderc, V., Kues, M., & Wetzel, B. (2022). Ultrasensitive Dispersive Fourier Transform Technique for Nonlinear Instability Characterization. Audiovisual publication https://doi.org/10.1364/FIO.2022.FTu1B.3
Sader L, Bose S, Kashi AK, Boussafa Y, Dauliat R, Roy P et al.. Ultrasensitive Dispersive Fourier Transform Technique for Nonlinear Instability Characterization 2022. doi: 10.1364/FIO.2022.FTu1B.3
Sader, Lynn (Author) ; Bose, Surajit (Author) ; Kashi, Anahita Khodadad (Author) et al.. / Ultrasensitive Dispersive Fourier Transform Technique for Nonlinear Instability Characterization. [Audiovisual publication].
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abstract = "We demonstrate the characterization of nonlinear noise-driven dynamics with ultrahigh sensitivity, resolution, and a theoretically unlimited dynamic range using a novel approach of dispersive Fourier transform-based measurements and multiple single photon detectors.",
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