Is it possible to deduce the ground state OH density from relative optical emission intensities of the OH(A 2Σ+-X 2Πi) transition in atmospheric pressure non-equilibrium plasmas? - An analysis of self-absorption

Yanjun Du; Zhimin Peng; Yanjun Ding; Nader Sadeghi; Peter J. Bruggeman

doi:10.1088/0963-0252/25/4/04LT02

Is it possible to deduce the ground state OH density from relative optical emission intensities of the OH(A ²Σ⁺-X ²Π_i) transition in atmospheric pressure non-equilibrium plasmas? - An analysis of self-absorption

Yanjun Du, Zhimin Peng, Yanjun Ding, Nader Sadeghi, Peter J. Bruggeman

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

8 Scopus citations

Abstract

The measurement of absolute densities of reactive species and radicals such as OH is of growing interest for many plasma applications. In this paper, we extend the use of a self-absorption model for atomic emission spectroscopy to molecular emission spectroscopy. The proposed analysis of self-absorbed molecular emission spectra is a simple and inexpensive method to determine OH(X) densities and rotational temperatures compared to laser induced fluorescence. We compare the recorded absolute OH density in a non-equilibrium diffuse atmospheric-pressure RF glow discharge by this method with broadband UV absorption considering a number of rotational lines with J′ 6.5, the detection limit of the line integrated OH(X) density with this method is of the order of 2 × 10¹⁹ m^-2. The accuracy of the density is sensitive to the rotational temperature of the OH(A) state and the non-equilibrium rotational population distribution.

Original language	English (US)
Article number	04LT02
Journal	Plasma Sources Science and Technology
Volume	25
Issue number	4
DOIs	https://doi.org/10.1088/0963-0252/25/4/04LT02
State	Published - Jul 13 2016
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2016 IOP Publishing Ltd.

Keywords

absorption
optical emission spectroscopy
radical densities
self-absorption

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Du, Y., Peng, Z., Ding, Y., Sadeghi, N., & Bruggeman, P. J. (2016). Is it possible to deduce the ground state OH density from relative optical emission intensities of the OH(A ²Σ⁺-X ²Π_i) transition in atmospheric pressure non-equilibrium plasmas? - An analysis of self-absorption. Plasma Sources Science and Technology, 25(4), Article 04LT02. https://doi.org/10.1088/0963-0252/25/4/04LT02

Is it possible to deduce the ground state OH density from relative optical emission intensities of the OH(A ²Σ⁺-X ²Π_i) transition in atmospheric pressure non-equilibrium plasmas? - An analysis of self-absorption. / Du, Yanjun; Peng, Zhimin; Ding, Yanjun et al.
In: Plasma Sources Science and Technology, Vol. 25, No. 4, 04LT02, 13.07.2016.

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

Du, Y, Peng, Z, Ding, Y, Sadeghi, N & Bruggeman, PJ 2016, 'Is it possible to deduce the ground state OH density from relative optical emission intensities of the OH(A ²Σ⁺-X ²Π_i) transition in atmospheric pressure non-equilibrium plasmas? - An analysis of self-absorption', Plasma Sources Science and Technology, vol. 25, no. 4, 04LT02. https://doi.org/10.1088/0963-0252/25/4/04LT02

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abstract = "The measurement of absolute densities of reactive species and radicals such as OH is of growing interest for many plasma applications. In this paper, we extend the use of a self-absorption model for atomic emission spectroscopy to molecular emission spectroscopy. The proposed analysis of self-absorbed molecular emission spectra is a simple and inexpensive method to determine OH(X) densities and rotational temperatures compared to laser induced fluorescence. We compare the recorded absolute OH density in a non-equilibrium diffuse atmospheric-pressure RF glow discharge by this method with broadband UV absorption considering a number of rotational lines with J′ 6.5, the detection limit of the line integrated OH(X) density with this method is of the order of 2 × 1019 m-2. The accuracy of the density is sensitive to the rotational temperature of the OH(A) state and the non-equilibrium rotational population distribution.",

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