Detection of OH and H2O in an Atmospheric Flame by Near-Infrared Optical Frequency Comb Spectroscopy

Lucile Rutkowski; Alexandra C. Johansson; Amir Khodabakhsh; Damir M. Valiev; Lorenzo Lodi; Sergey Yurchenko; Oleg L. Polyansky; Jonathan Tennyson; Florian M. Schmidt; Aleksandra Foltynowicz

2017 European Conference on Lasers and Electro-Optics and European Quantum Electronics Conference
(Optica Publishing Group, 2017),
paper CH_P_29

Detection of OH and H₂O in an Atmospheric Flame by Near-Infrared Optical Frequency Comb Spectroscopy

Lucile Rutkowski, Alexandra C. Johansson, Amir Khodabakhsh, Damir M. Valiev, Lorenzo Lodi, Sergey Yurchenko, Oleg L. Polyansky, Jonathan Tennyson, Florian M. Schmidt, and Aleksandra Foltynowicz

The European Conference on Lasers and Electro-Optics 2017

Munich Germany
25–29 June 2017
ISBN: 978-1-5090-6736-7

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L. Rutkowski, A. C. Johansson, A. Khodabakhsh, D. M. Valiev, L. Lodi, S. Yurchenko, O. L. Polyansky, J. Tennyson, F. M. Schmidt, and A. Foltynowicz, "Detection of OH and H2O in an Atmospheric Flame by Near-Infrared Optical Frequency Comb Spectroscopy," in 2017 European Conference on Lasers and Electro-Optics and European Quantum Electronics Conference, (Optica Publishing Group, 2017), paper CH_P_29.

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Abstract

Absorption spectroscopy is attractive for combustion diagnostics because it allows in-situ and calibration-free quantification of reactants/products and thermometry. However, spectra measured at atmospheric pressure in the near-infrared telecom range, where laser sources and optical components are readily available, suffer from strong water interference. Cavity-enhanced optical frequency comb spectroscopy (CE-OFCS) is well suited for detection of other species, as it provides broad bandwidth with high signal-to-noise ratio and resolution, and allows de-convolving the spectra hidden among water transitions. Here we report detection of OH in the presence of H₂O in an atmospheric premixed methane/air flat flame by CE-OFCS at 1.57 μm. We demonstrate a new water line list that is more accurate than HITEMP [1] and we isolate the OH lines by dividing spectra taken at different heights above the burner (HABs) to retrieve OH concentration and flame temperature.

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