An exploratory modelling study of chemiluminescence in ammonia-fuelled flames. Part 1

Konnov, Alexander A.

An exploratory modelling study of chemiluminescence in ammonia-fuelled flames. Part 1

Mark

Konnov, Alexander A. ^LU (2023) In Combustion and Flame 253.

Abstract: The present exploratory study is aimed at the modelling of the chemiluminescence signature of premixed laminar NH₃+H₂+air flames. The detailed kinetic mechanism of the author was extended by reactions describing the formation and consumption of excited NO₂*, NO(A), NH*, and NH₂* mostly relying on previous analyses of chemiluminescence processes from the literature. The lowest-lying excited state of molecular nitrogen, N₂(A) is also invoked to analyse its possible impact on the formation of these emitting species. In the present model, the formation of NO(A) and NH* in NH₃+H₂+air flames is governed by the energy transfer from N₂(A) to the ground state... (More); The present exploratory study is aimed at the modelling of the chemiluminescence signature of premixed laminar NH₃+H₂+air flames. The detailed kinetic mechanism of the author was extended by reactions describing the formation and consumption of excited NO₂*, NO(A), NH*, and NH₂* mostly relying on previous analyses of chemiluminescence processes from the literature. The lowest-lying excited state of molecular nitrogen, N₂(A) is also invoked to analyse its possible impact on the formation of these emitting species. In the present model, the formation of NO(A) and NH* in NH₃+H₂+air flames is governed by the energy transfer from N₂(A) to the ground state NO and NH, respectively. The new model predictions are compared with available experimental data obtained by Zhu et al. in laminar counterflow NH₃+H₂+air flames (PROCI 39 (2023)). Good agreement with the measurements was demonstrated for NO(A), OH*, and NH*, both in terms of their variation with equivalence ratio and the amounts of ammonia in the fuel. Moreover, the model qualitatively captures the ratios of chemiluminescence intensity of OH*/NO(A), NH*/OH* and NH*/NO(A). Further analysis revealed that the bimodal behaviour of chemiluminescence in the spectral regions identified by Zhu et al. as “blue”, “green”, “yellow”, “orange”, and “red”, can be explained by the interplay of emissions from NO₂* and NH₂*, while emission in the “violet” spectral band could be assigned to excited H₂O*.
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Please use this url to cite or link to this publication: https://lup.lub.lu.se/record/777af924-23e4-44f1-a8b8-cc141774c116

author

Konnov, Alexander A. ^LU

organization

publishing date

2023

type

Contribution to journal

publication status

published

subject

Atom and Molecular Physics and Optics

keywords

Ammonia, Chemiluminescence, Flame, Kinetic model

in

Combustion and Flame

volume

253

article number

112788

publisher

Elsevier

external identifiers

scopus:85153955711

ISSN

0010-2180

DOI

10.1016/j.combustflame.2023.112788

language

English

LU publication?

yes

id

777af924-23e4-44f1-a8b8-cc141774c116

date added to LUP

2023-07-17 12:24:51

date last changed

2023-11-08 07:42:43

@article{777af924-23e4-44f1-a8b8-cc141774c116,
  abstract     = {{<p>The present exploratory study is aimed at the modelling of the chemiluminescence signature of premixed laminar NH<sub>3</sub>+H<sub>2</sub>+air flames. The detailed kinetic mechanism of the author was extended by reactions describing the formation and consumption of excited NO<sub>2</sub>*, NO(A), NH*, and NH<sub>2</sub>* mostly relying on previous analyses of chemiluminescence processes from the literature. The lowest-lying excited state of molecular nitrogen, N<sub>2</sub>(A) is also invoked to analyse its possible impact on the formation of these emitting species. In the present model, the formation of NO(A) and NH* in NH<sub>3</sub>+H<sub>2</sub>+air flames is governed by the energy transfer from N<sub>2</sub>(A) to the ground state NO and NH, respectively. The new model predictions are compared with available experimental data obtained by Zhu et al. in laminar counterflow NH<sub>3</sub>+H<sub>2</sub>+air flames (PROCI 39 (2023)). Good agreement with the measurements was demonstrated for NO(A), OH*, and NH*, both in terms of their variation with equivalence ratio and the amounts of ammonia in the fuel. Moreover, the model qualitatively captures the ratios of chemiluminescence intensity of OH*/NO(A), NH*/OH* and NH*/NO(A). Further analysis revealed that the bimodal behaviour of chemiluminescence in the spectral regions identified by Zhu et al. as “blue”, “green”, “yellow”, “orange”, and “red”, can be explained by the interplay of emissions from NO<sub>2</sub>* and NH<sub>2</sub>*, while emission in the “violet” spectral band could be assigned to excited H<sub>2</sub>O*.</p>}},
  author       = {{Konnov, Alexander A.}},
  issn         = {{0010-2180}},
  keywords     = {{Ammonia; Chemiluminescence; Flame; Kinetic model}},
  language     = {{eng}},
  publisher    = {{Elsevier}},
  series       = {{Combustion and Flame}},
  title        = {{An exploratory modelling study of chemiluminescence in ammonia-fuelled flames. Part 1}},
  url          = {{http://dx.doi.org/10.1016/j.combustflame.2023.112788}},
  doi          = {{10.1016/j.combustflame.2023.112788}},
  volume       = {{253}},
  year         = {{2023}},
}

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An exploratory modelling study of chemiluminescence in ammonia-fuelled flames. Part 1