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Cationic structure of premixed near-stoichiometric CH4/O2/Ar flames at atmospheric pressure: New insights from mass spectrometry, quantum chemistry, and kinetic modeling. / Knyazkov, Denis A.; Gerasimov, Ilya E.; Bolshova, Tatyana A. и др.

в: Combustion and Flame, Том 241, 112106, 07.2022.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

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@article{0ed6b02a10ba4c14a5e7928a8d957e0d,
title = "Cationic structure of premixed near-stoichiometric CH4/O2/Ar flames at atmospheric pressure: New insights from mass spectrometry, quantum chemistry, and kinetic modeling",
abstract = "The spatial distributions of naturally occurring cations in near-stoichiometric (equivalence ratios ϕ = 0.8 and 1.2) burner-stabilized methane/oxygen/argon flames at atmospheric pressure are studied by molecular beam mass spectrometry (MBMS) and kinetic modeling. The disturbing effect of a nickel sampling cone used in the measurements on the flame was comprehensively modeled using a two-dimensional direct numerical simulation of reacting flow near the axially symmetric probe along with a reduced chemical kinetic mechanism. The use of one-dimensional numerical simulation for predicting the flame structure perturbed by the metallic probe was firmly justified. We also proposed and applied a procedure to correct the measured spatial profiles of cations on the contribution of signals from the hydrates formed slightly upstream the reaction zone due to the sampling probe effects. With all these methodological advantages, we validated the ion chemistry mechanisms proposed earlier in the literature against the novel experimental data on the spatial distributions of the following cations: HCO+, CH3+, H3O+, C2H3O+, CH5O+, C3H3+. The kinetic mechanism published recently by Chen et al. [Combust. Flame 202 (2019) 208] for the charged species formed in methane flames was revised in order to improve its predictive ability. To this end, the highly accurate W2-F12 quantum chemical calculations were used to obtain the reliable formation enthalpies of all cations considered in the mechanism. In the case of C2H3O+ and C3H3+ cations, the calculated values turned out to be profoundly lower than those reported before. Apart from this, the theory also predicted another exit channel for H3O+ + acetylene reaction yielding HCO+ + CH4 instead of C2H3O+ + H2 proposed earlier. The corrections significantly improved the predictive ability of the ion chemistry mechanism. We also considered the most important directions for the further refinement of the mechanism.",
keywords = "Electric-field assisted combustion, Flame ionization, Flame sampling molecular beam mass spectrometry, Ions in flames, Quantum chemistry",
author = "Knyazkov, {Denis A.} and Gerasimov, {Ilya E.} and Bolshova, {Tatyana A.} and Kiselev, {Vitaly G.} and Shmakov, {Andrey G.} and Paletsky, {Alexander A.}",
note = "Funding Information: The research presented in this paper in Sections 2.1 , 3.2 and 3.4 was carried out within the RFBR grant (project No. 19–03–0058 9). The results reported in Sections 2.4 and 3.1 were obtained within the grant from the Government of the Russian Federation (project No. 075–15–2019–1888 ). The study represented in Sections 2.2 , 2.6 and 3.3 was performed within the RSF grant (project No. 21–13–00434 ). Publisher Copyright: {\textcopyright} 2022 The Combustion Institute",
year = "2022",
month = jul,
doi = "10.1016/j.combustflame.2022.112106",
language = "English",
volume = "241",
journal = "Combustion and Flame",
issn = "0010-2180",
publisher = "Elsevier Science Inc.",

}

RIS

TY - JOUR

T1 - Cationic structure of premixed near-stoichiometric CH4/O2/Ar flames at atmospheric pressure: New insights from mass spectrometry, quantum chemistry, and kinetic modeling

AU - Knyazkov, Denis A.

AU - Gerasimov, Ilya E.

AU - Bolshova, Tatyana A.

AU - Kiselev, Vitaly G.

AU - Shmakov, Andrey G.

AU - Paletsky, Alexander A.

N1 - Funding Information: The research presented in this paper in Sections 2.1 , 3.2 and 3.4 was carried out within the RFBR grant (project No. 19–03–0058 9). The results reported in Sections 2.4 and 3.1 were obtained within the grant from the Government of the Russian Federation (project No. 075–15–2019–1888 ). The study represented in Sections 2.2 , 2.6 and 3.3 was performed within the RSF grant (project No. 21–13–00434 ). Publisher Copyright: © 2022 The Combustion Institute

PY - 2022/7

Y1 - 2022/7

N2 - The spatial distributions of naturally occurring cations in near-stoichiometric (equivalence ratios ϕ = 0.8 and 1.2) burner-stabilized methane/oxygen/argon flames at atmospheric pressure are studied by molecular beam mass spectrometry (MBMS) and kinetic modeling. The disturbing effect of a nickel sampling cone used in the measurements on the flame was comprehensively modeled using a two-dimensional direct numerical simulation of reacting flow near the axially symmetric probe along with a reduced chemical kinetic mechanism. The use of one-dimensional numerical simulation for predicting the flame structure perturbed by the metallic probe was firmly justified. We also proposed and applied a procedure to correct the measured spatial profiles of cations on the contribution of signals from the hydrates formed slightly upstream the reaction zone due to the sampling probe effects. With all these methodological advantages, we validated the ion chemistry mechanisms proposed earlier in the literature against the novel experimental data on the spatial distributions of the following cations: HCO+, CH3+, H3O+, C2H3O+, CH5O+, C3H3+. The kinetic mechanism published recently by Chen et al. [Combust. Flame 202 (2019) 208] for the charged species formed in methane flames was revised in order to improve its predictive ability. To this end, the highly accurate W2-F12 quantum chemical calculations were used to obtain the reliable formation enthalpies of all cations considered in the mechanism. In the case of C2H3O+ and C3H3+ cations, the calculated values turned out to be profoundly lower than those reported before. Apart from this, the theory also predicted another exit channel for H3O+ + acetylene reaction yielding HCO+ + CH4 instead of C2H3O+ + H2 proposed earlier. The corrections significantly improved the predictive ability of the ion chemistry mechanism. We also considered the most important directions for the further refinement of the mechanism.

AB - The spatial distributions of naturally occurring cations in near-stoichiometric (equivalence ratios ϕ = 0.8 and 1.2) burner-stabilized methane/oxygen/argon flames at atmospheric pressure are studied by molecular beam mass spectrometry (MBMS) and kinetic modeling. The disturbing effect of a nickel sampling cone used in the measurements on the flame was comprehensively modeled using a two-dimensional direct numerical simulation of reacting flow near the axially symmetric probe along with a reduced chemical kinetic mechanism. The use of one-dimensional numerical simulation for predicting the flame structure perturbed by the metallic probe was firmly justified. We also proposed and applied a procedure to correct the measured spatial profiles of cations on the contribution of signals from the hydrates formed slightly upstream the reaction zone due to the sampling probe effects. With all these methodological advantages, we validated the ion chemistry mechanisms proposed earlier in the literature against the novel experimental data on the spatial distributions of the following cations: HCO+, CH3+, H3O+, C2H3O+, CH5O+, C3H3+. The kinetic mechanism published recently by Chen et al. [Combust. Flame 202 (2019) 208] for the charged species formed in methane flames was revised in order to improve its predictive ability. To this end, the highly accurate W2-F12 quantum chemical calculations were used to obtain the reliable formation enthalpies of all cations considered in the mechanism. In the case of C2H3O+ and C3H3+ cations, the calculated values turned out to be profoundly lower than those reported before. Apart from this, the theory also predicted another exit channel for H3O+ + acetylene reaction yielding HCO+ + CH4 instead of C2H3O+ + H2 proposed earlier. The corrections significantly improved the predictive ability of the ion chemistry mechanism. We also considered the most important directions for the further refinement of the mechanism.

KW - Electric-field assisted combustion

KW - Flame ionization

KW - Flame sampling molecular beam mass spectrometry

KW - Ions in flames

KW - Quantum chemistry

UR - http://www.scopus.com/inward/record.url?scp=85126879671&partnerID=8YFLogxK

U2 - 10.1016/j.combustflame.2022.112106

DO - 10.1016/j.combustflame.2022.112106

M3 - Article

AN - SCOPUS:85126879671

VL - 241

JO - Combustion and Flame

JF - Combustion and Flame

SN - 0010-2180

M1 - 112106

ER -

ID: 35769295