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LIF-imaging of temperature and iron-atom concentration in iron nitrate doped low-pressure aerosol flat flames

•Combustion of iron(III) nitrate/1-butanol aerosols was studied in a novel matrix burner.•OH LIF and Fe LIF were used for temperature and Fe atom detection in the flame.•Unexpectedly, no effect on the flame temperature was detected with up to 400 ppm iron(III) nitrate.•Kinetic models for Fe-doped fl...

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Bibliographic Details
Published in:Applications in energy and combustion science 2023-12, Vol.16, p.100199, Article 100199
Main Authors: Apazeller, Sascha, Karaminejad, Sadrollah, Nanjaiah, Monika, Wiggers, Hartmut, Endres, Torsten, Wlokas, Irenäus, Schulz, Christof
Format: Article
Language:English
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Summary:•Combustion of iron(III) nitrate/1-butanol aerosols was studied in a novel matrix burner.•OH LIF and Fe LIF were used for temperature and Fe atom detection in the flame.•Unexpectedly, no effect on the flame temperature was detected with up to 400 ppm iron(III) nitrate.•Kinetic models for Fe-doped flames need to be extended by particle-surface reactions. To enable the investigation of the flame chemistry of precursor-laden nanoparticle forming spray flames in quasi-one-dimensional geometry, a matrix burner was developed in which a laminar flat flame is uniformly supplied with liquid aerosol. In the present work, the burner was used to study the interaction of iron(III) nitrate as precursor dissolved in 1-butanol with the flame. Distributions of temperature and relative iron-atom concentrations were measured via OH and Fe laser-induced fluorescence imaging, respectively. Elastic laser light scattering was used to determine the spatial distribution of particles and droplets to characterize the burner and to obtain insight into the particle formation process. The matrix burner was operated with hydrogen or methane. The measured flame temperatures were compared with one- and three-dimensional CFD simulations supporting the development of reaction mechanisms for precursor-laden flames.
ISSN:2666-352X
2666-352X
DOI:10.1016/j.jaecs.2023.100199