Time-resolved HO2 detection with Faraday rotation spectroscopy in a photolysis reactor

Chu C. Teng; Chao Yan; Aric Rousso; Hongtao Zhong; Timothy Chen; Eric J. Zhang; Yiguang Ju; Gerard Wysocki

doi:10.1364/OE.413063

Time-resolved HO₂ detection with Faraday rotation spectroscopy in a photolysis reactor

Chu C. Teng, Chao Yan, Aric Rousso, Hongtao Zhong, Timothy Chen, Eric J. Zhang, Yiguang Ju, Gerard Wysocki

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

9 Scopus citations

Abstract

Faraday rotation spectroscopy (FRS) employs the Faraday effect to detect Zeeman splitting in the presence of a magnetic field. In this article, we present system design and implementation of radical sensing in a photolysis reactor using FRS. High sensitivity (100 ppb) and time resolved in situ HO₂ detection is enabled with a digitally balanced acquisition scheme. Specific advantages of employing FRS for sensing in such dynamic environments are examined and rigorously compared to the more established conventional laser absorption spectroscopy (LAS). Experimental results show that FRS enables HO₂ detection when LAS is deficient, and FRS compares favorably in terms of precision when LAS is applicable. The immunity of FRS to spectral interferences such as absorption of hydrocarbons and other diamagnetic species absorption and optical fringing are highlighted in comparison to LAS.

Original language	English (US)
Pages (from-to)	2769-2779
Number of pages	11
Journal	Optics Express
Volume	29
Issue number	2
DOIs	https://doi.org/10.1364/OE.413063
State	Published - Jan 18 2021

All Science Journal Classification (ASJC) codes

Atomic and Molecular Physics, and Optics

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10.1364/OE.413063

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title = "Time-resolved HO2 detection with Faraday rotation spectroscopy in a photolysis reactor",

abstract = "Faraday rotation spectroscopy (FRS) employs the Faraday effect to detect Zeeman splitting in the presence of a magnetic field. In this article, we present system design and implementation of radical sensing in a photolysis reactor using FRS. High sensitivity (100 ppb) and time resolved in situ HO2 detection is enabled with a digitally balanced acquisition scheme. Specific advantages of employing FRS for sensing in such dynamic environments are examined and rigorously compared to the more established conventional laser absorption spectroscopy (LAS). Experimental results show that FRS enables HO2 detection when LAS is deficient, and FRS compares favorably in terms of precision when LAS is applicable. The immunity of FRS to spectral interferences such as absorption of hydrocarbons and other diamagnetic species absorption and optical fringing are highlighted in comparison to LAS.",

author = "Teng, {Chu C.} and Chao Yan and Aric Rousso and Hongtao Zhong and Timothy Chen and Zhang, {Eric J.} and Yiguang Ju and Gerard Wysocki",

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T1 - Time-resolved HO2 detection with Faraday rotation spectroscopy in a photolysis reactor

AU - Teng, Chu C.

AU - Yan, Chao

AU - Rousso, Aric

AU - Zhong, Hongtao

AU - Chen, Timothy

AU - Zhang, Eric J.

AU - Ju, Yiguang

AU - Wysocki, Gerard

PY - 2021/1/18

Y1 - 2021/1/18

N2 - Faraday rotation spectroscopy (FRS) employs the Faraday effect to detect Zeeman splitting in the presence of a magnetic field. In this article, we present system design and implementation of radical sensing in a photolysis reactor using FRS. High sensitivity (100 ppb) and time resolved in situ HO2 detection is enabled with a digitally balanced acquisition scheme. Specific advantages of employing FRS for sensing in such dynamic environments are examined and rigorously compared to the more established conventional laser absorption spectroscopy (LAS). Experimental results show that FRS enables HO2 detection when LAS is deficient, and FRS compares favorably in terms of precision when LAS is applicable. The immunity of FRS to spectral interferences such as absorption of hydrocarbons and other diamagnetic species absorption and optical fringing are highlighted in comparison to LAS.

AB - Faraday rotation spectroscopy (FRS) employs the Faraday effect to detect Zeeman splitting in the presence of a magnetic field. In this article, we present system design and implementation of radical sensing in a photolysis reactor using FRS. High sensitivity (100 ppb) and time resolved in situ HO2 detection is enabled with a digitally balanced acquisition scheme. Specific advantages of employing FRS for sensing in such dynamic environments are examined and rigorously compared to the more established conventional laser absorption spectroscopy (LAS). Experimental results show that FRS enables HO2 detection when LAS is deficient, and FRS compares favorably in terms of precision when LAS is applicable. The immunity of FRS to spectral interferences such as absorption of hydrocarbons and other diamagnetic species absorption and optical fringing are highlighted in comparison to LAS.

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Time-resolved HO₂ detection with Faraday rotation spectroscopy in a photolysis reactor

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