Flame structure of laminar premixed HC(O)OH/O2/Ar was studied both experimentally and numerically. Three available chemical kinetic models were tested. In general, all models agree with experimental results for H2O, CO, O2, CO2, HC(O)OH within the experimental error. For most of the intermediates all the models well capture the peak position and concentration profiles shape.
REFERENCES
1.
J.
Eppinger
and K.-W.
Huang
, ACS Energy Lett.
2
(1
), 188
–195
(2017
).2.
K.
Sordakis
, C.
Tang
, L. K.
Vogt
, H.
Junge
, P. J.
Dyson
, M.
Beller
and G.
Laurenczy
, Chem. Rev.
118
, 372
– 433
(2018
).3.
X.
Wang
, Q.
Meng
, L.
Gao
, Z.
Jin
, J.
Ge
, C.
Liu
and W.
Xing
, Int. J. Hydrog. Energy
43
(14
), 7055
–7071
(2018
).4.
W.A.
Bone
and J.B.
Gardner
, Proc. Roy. Soc. Lond. A
154
, 297
–328
(1936
).5.
A.G.
Gaydon
and H.G.
Wolfhard
, Symp. Combust. Flame Explos. Phenom.
3
(1
), 504
–518
(1949
).6.
E.
de Wilde
and A.
van Tiggelen
, Bull. Soc. Chim. Belges
77
, 67
–76
(1968
).7.
8.
P.G.
Blake
, H.H.
Davies
and G.E.
Jackson
, J. Chem. Soc. B
10
, 1923
–1925
(1971
).9.
D.S.Y.
Hsu
, W.M.
Shaub
, M.
Blackburn
and M.C.
Lin
, Proc. Combust. Inst.
19
, 89
–96
(1982
).10.
K.
Saito
, T.
Kakumoto
, H.
Kuroda
, S.
Torii
and A.
Imamura
, J. Chem. Phys.
80
, 4989
–4996
(1984
).11.
K.
Saito
, T.
Shiose
, O.
Takahashi
, Y.
Hidaka
, F.
Aiba
and K.
Tabayashi
, J. Phys. Chem. A
109
, 5352
–5357
(2005
).12.
A.
Elwardany
, E.F.
Nasir
, Et.
Es-sebbar
and A.
Farooq
, Proc. Combust Inst.
35
,) 429
–436
(2015
).13.
M.
Klatt
, M.
Rohrig
and H.G.
Wagner
, Z. Naturforsch
47
, 1138
–1140
(1992
).14.
N.M.
Marinov
, Int. J. Chem. Kin.
31
, 183
–220
(1999
).15.
S.L.
Fischer
, F.L.
Dryer
and H.J.
Curran
, Int. J. Chem. Kin.
32
, 713
–740
(2000
).16.
F.
Battin-Leclerc
, A.A.
Konnov
, J.L.
Jaffrezo
and M.
Legrand
, Combust. Sci. Technol.
180
, 343
–370
(2007
).17.
M.
Christensen
and A. A.
Konnov
, Combust. Flame
170
, 12
–29
(2016
).18.
S.
Namysl
, M.
Pelucchi
O.
Herbinet
, A.
Frassoldati
, T.
Faravelli
and F.
Battin-Leclerc
, Chem. Eng. J.
373
, 973
–984
(2019
).19.
P.
Marshall
and P.
Glarborg
, Proc. Combust. Inst.
35
, 153
–160
(2015
).20.
S. M.
Sarathy
, P.
Brequigny
, A.
Katoch
, A.M.
Elbaz
, W. L.
Roberts
, R. W.
Dibble
and F.
Foucher
, Energ. Fuel.
34
(6
), 7564
–7572
(2020
).21.
Saudi Aramco mechanism release v. 2.0
, Combustion Chemistry Centre
, National University of Ireland
, Galway
, (2016
).22.
G.
Yin
, Q.
Gao
, E.
Hu
, J.
Xu
, M.
Zhou
and Z.
Huang
, Combust. Flame
220
, 73
–81
(2020
).23.
Saudi Aramco mechanism release v. 3.0
, Combustion Chemistry Centre
, National University of Ireland
, Galway
, (2018
).24.
25.
K. N.
Osipova
, T. A.
Bolshova
, O. P.
Korobeinichev
, L. V.
Kuibida
and A. G.
Shmakov
, Energ. Fuel.
33
, 4585
−4597
(2019
).26.
A. M.
Dmitriev
, K. N.
Osipova
, D. A.
Knyazkov
, I. E.
Gerasimov
, A. G.
Shmakov
and O. P.
Korobeinichev
, Combust. Explos. Shock Waves
54
, 125
−135
(2018
).27.
T.A.
Cool
, K.
Nakajima
, K.A.
Taatjes
, A.
McIlroy
, P.R.
Westmoreland
, M.E.
Law
and A.
Morel
, Proc. Combust. Inst.
30
, 1681
–1688
(2005
).29.
A.
Lamprecht
, B.
Atakan
and K.
Kohse-Hoeinghaus
, Combust. Flame
122
, 483
−491
(2000
).30.
W. L.
Fitch
and A. D.
Sauter
, Anal. Chem.
55
, 832
−835
, (1983
).31.
I. E.
Gerasimov
, D. A.
Knyazkov
, S. A.
Yakimov
, T. A.
Bolshova
, A. G.
Shmakov
and O. P.
Korobeinichev
, Combust. Flame
159
, 1840
−1850
(2012
).
This content is only available via PDF.
© 2020 Author(s).
2020
Author(s)
You do not currently have access to this content.