Combustion and pyrolysis of iso-butanol: Experimental and chemical kinetic modeling study

SS Merchant, EF Zanoelo, RL Speth, MR Harper… - Combustion and …, 2013 - Elsevier
Combustion and Flame, 2013Elsevier
The first reaction mechanism for iso-butanol (372 species and 8723 reversible elementary
reactions) pyrolysis and combustion that includes pressure dependent kinetics and
proposes reaction pathways to soot precursors has been automatically generated using the
open-source software package RMG. High-pressure reaction rate coefficients for important
hydrogen abstraction reactions from iso-butanol by hydrogen, methyl and HO 2 were
calculated using quantum chemistry at the CBS-QB3 level. The mechanism was validated …
Abstract
The first reaction mechanism for iso-butanol (372 species and 8723 reversible elementary reactions) pyrolysis and combustion that includes pressure dependent kinetics and proposes reaction pathways to soot precursors has been automatically generated using the open-source software package RMG. High-pressure reaction rate coefficients for important hydrogen abstraction reactions from iso-butanol by hydrogen, methyl and HO2 were calculated using quantum chemistry at the CBS-QB3 level. The mechanism was validated with recently published iso-butanol combustion experiments as well as new pyrolysis speciation data under diluted and undiluted conditions from 900 to 1100 K at 1.72 atm representative of fuel rich combustion conditions. Sensitivity and rate of production analysis revealed that the overall good agreement for the pyrolysis species, and in particular for the soot precursors like benzene, toluene and 1,3-cyclopentadiene, depends strongly on pressure dependent reactions involving the resonantly stabilized iso-butenyl radical. Laminar flame speed, opposed flow diffusion flame speciation profiles, and autoignition are also well-captured by the model. The agreement with speciation profiles for the jet-stirred reactor could be improved, in particular for temperatures lower than 850 K. Flux and sensitivity analysis for iso-butanol consumption revealed that this is primarily caused by uncertainty in iso-butanol + OH, iso-butanol + HO2 and the low temperature peroxy chemistry rates. Further theoretical and quantum chemical studies are needed in understanding these rates to completely predict the combustion behavior of iso-butanol using detailed chemistry.
Elsevier
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