Development of Two-Color Laser Imaging Interferometer Using CO2 Laser and Quantum Cascade Laser in the Large Helical Device

Development of Two-Color Laser Imaging Interferometer Using CO2 Laser and Quantum Cascade Laser in the Large Helical Device

CO2 laser interferometers are a promising option for high-density plasma measurements. However, in low- and middle-density measurements, noise due to mechanical vibrations is a serious problem. To remove this noise, we developed a two-color laser imaging interferometer using a CO2 laser and quantum...

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Veröffentlicht in:Plasma and Fusion Research 2022/12/09, Vol.17, pp.1402107-1402107
Hauptverfasser: KINOSHITA, Toshiki, TANAKA, Kenji, TAKEMURA, Yuki, TAKESHIDA, Shota, SAKAI, Hikona
Format: Artikel
Sprache:eng
Schlagworte:
Carbon dioxide
Carbon dioxide lasers
CO2 laser
Color
Electron density profiles
High temperature plasmas
Imaging
interferometer
Interferometers
Lasers
LHD
Optical design
plasma diagnostics
quantum cascade laser
Quantum cascade lasers
Stability analysis
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container_issue
container_start_page 1402107
container_title Plasma and Fusion Research
container_volume 17
creator KINOSHITA, Toshiki
TANAKA, Kenji
TAKEMURA, Yuki
TAKESHIDA, Shota
SAKAI, Hikona
description CO2 laser interferometers are a promising option for high-density plasma measurements. However, in low- and middle-density measurements, noise due to mechanical vibrations is a serious problem. To remove this noise, we developed a two-color laser imaging interferometer using a CO2 laser and quantum cascade (QC) laser, called the CO2/QC laser imaging interferometer, through benchtop experiments and installed it in the Large Helical Device (LHD). Benchtop experiments provided optical design guidelines for the CO2/QC laser imaging interferometer to minimize the influence of the unstable output wavelength of the QC laser. The optical system in LHD was designed according to this guideline, and the vibration noise was successfully reduced to 2.80 × 1018 m-3. We also demonstrate measurement examples of hollowed and peaked electron density profiles evaluated using Abel inversion and macro-scale instability. This is the first study to present the measurement results of high-temperature plasma using a CO2/QC two-color laser interferometer. The study outcomes provide important insights for the development of two-color laser interferometers in future fusion devices.
doi_str_mv 10.1585/pfr.17.1402107
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source J-STAGE Free; Elektronische Zeitschriftenbibliothek - Frei zugängliche E-Journals
subjects Carbon dioxide
Carbon dioxide lasers
CO2 laser
Color
Electron density profiles
High temperature plasmas
Imaging
interferometer
Interferometers
Lasers
LHD
Optical design
plasma diagnostics
quantum cascade laser
Quantum cascade lasers
Stability analysis
title Development of Two-Color Laser Imaging Interferometer Using CO2 Laser and Quantum Cascade Laser in the Large Helical Device
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