Different elements, same results: time-resolved temperature determination by oxygen and nitrogen elements

S. Arjmand; M. P. Anania; A. Biagioni; M. Ferrario; M. Galletti; V. Lollo; D. Pellegrini; R. Pompili; A. Zigler

doi:10.1088/1748-0221/18/08/P08003

Different elements, same results: time-resolved temperature determination by oxygen and nitrogen elements

S. Arjmand^*, M. P. Anania, A. Biagioni, M. Ferrario, M. Galletti, V. Lollo, D. Pellegrini, R. Pompili, A. Zigler

^*Corresponding author for this work

Racah Institute of Physics

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

The core purpose of this research is to use optical emission spectroscopy to determine the electron temperature (T_e ) of a hydrogen plasma generated in a capillary discharge plasma, with a focus on its temporal variation. The plasma density (n_e ) is first determined using the Stark broadening technique, which measures the broadening of spectral lines as a result of the electric field in the plasma. Subsequently, a passive spectroscopic technique is employed to estimate the electron plasma temperature by detecting the emitted light from the plasma. This spectral detection is performed using a visible range spectrometer. In this study, two elements, oxygen and nitrogen, are specifically selected based on the chemical composition of the capillary. The electron plasma temperature is estimated using the line ratio method, which involves comparing the intensities of two specific spectral lines emitted by the selected elements. By analyzing these line ratios, the electron plasma temperature can be inferred. The combination of the Stark broadening technique and line ratio method provides valuable insights into the plasma's physical characteristics, specifically its density and temperature.

Original language	English
Article number	P08003
Journal	Journal of Instrumentation
Volume	18
Issue number	8
DOIs	https://doi.org/10.1088/1748-0221/18/08/P08003
State	Published - 1 Aug 2023

Bibliographical note

Publisher Copyright:
© 2023 The Author(s)

Keywords

Plasma diagnostics - charged-particle spectroscopy
Plasma diagnostics - interferometry, spectroscopy and imaging
Wake-field acceleration (laser-driven, electron-driven)

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10.1088/1748-0221/18/08/P08003

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title = "Different elements, same results: time-resolved temperature determination by oxygen and nitrogen elements",

abstract = "The core purpose of this research is to use optical emission spectroscopy to determine the electron temperature (Te ) of a hydrogen plasma generated in a capillary discharge plasma, with a focus on its temporal variation. The plasma density (ne ) is first determined using the Stark broadening technique, which measures the broadening of spectral lines as a result of the electric field in the plasma. Subsequently, a passive spectroscopic technique is employed to estimate the electron plasma temperature by detecting the emitted light from the plasma. This spectral detection is performed using a visible range spectrometer. In this study, two elements, oxygen and nitrogen, are specifically selected based on the chemical composition of the capillary. The electron plasma temperature is estimated using the line ratio method, which involves comparing the intensities of two specific spectral lines emitted by the selected elements. By analyzing these line ratios, the electron plasma temperature can be inferred. The combination of the Stark broadening technique and line ratio method provides valuable insights into the plasma's physical characteristics, specifically its density and temperature.",

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doi = "10.1088/1748-0221/18/08/P08003",

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AU - Arjmand, S.

AU - Anania, M. P.

AU - Biagioni, A.

AU - Ferrario, M.

AU - Galletti, M.

AU - Lollo, V.

AU - Pellegrini, D.

AU - Pompili, R.

AU - Zigler, A.

PY - 2023/8/1

Y1 - 2023/8/1

N2 - The core purpose of this research is to use optical emission spectroscopy to determine the electron temperature (Te ) of a hydrogen plasma generated in a capillary discharge plasma, with a focus on its temporal variation. The plasma density (ne ) is first determined using the Stark broadening technique, which measures the broadening of spectral lines as a result of the electric field in the plasma. Subsequently, a passive spectroscopic technique is employed to estimate the electron plasma temperature by detecting the emitted light from the plasma. This spectral detection is performed using a visible range spectrometer. In this study, two elements, oxygen and nitrogen, are specifically selected based on the chemical composition of the capillary. The electron plasma temperature is estimated using the line ratio method, which involves comparing the intensities of two specific spectral lines emitted by the selected elements. By analyzing these line ratios, the electron plasma temperature can be inferred. The combination of the Stark broadening technique and line ratio method provides valuable insights into the plasma's physical characteristics, specifically its density and temperature.

AB - The core purpose of this research is to use optical emission spectroscopy to determine the electron temperature (Te ) of a hydrogen plasma generated in a capillary discharge plasma, with a focus on its temporal variation. The plasma density (ne ) is first determined using the Stark broadening technique, which measures the broadening of spectral lines as a result of the electric field in the plasma. Subsequently, a passive spectroscopic technique is employed to estimate the electron plasma temperature by detecting the emitted light from the plasma. This spectral detection is performed using a visible range spectrometer. In this study, two elements, oxygen and nitrogen, are specifically selected based on the chemical composition of the capillary. The electron plasma temperature is estimated using the line ratio method, which involves comparing the intensities of two specific spectral lines emitted by the selected elements. By analyzing these line ratios, the electron plasma temperature can be inferred. The combination of the Stark broadening technique and line ratio method provides valuable insights into the plasma's physical characteristics, specifically its density and temperature.

KW - Plasma diagnostics - charged-particle spectroscopy

KW - Plasma diagnostics - interferometry, spectroscopy and imaging

KW - Wake-field acceleration (laser-driven, electron-driven)

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Different elements, same results: time-resolved temperature determination by oxygen and nitrogen elements

Abstract

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Keywords

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