Gabriel da Silva 1 , Adam J Trevitt Show Affiliations »
Abstract
This study uses computational chemistry and statistical reaction rate theory to investigate the chemically activated reaction of diacetylene (butadiyne, C(4)H(2)) with the propargyl radical (C˙H(2)CCH) and the reaction of acetylene (C(2)H(2)) with the i-C(5)H(3) (CH(2)CCCC˙H) and n-C(5)H(3) (CHCC˙HCCH) radicals. A detailed G3SX-level C(7)H(5) energy surface demonstrates that the C(3)H(3) + C(4)H(2) and C(5)H(3) + C(2)H(2) addition reactions proceed with moderate barriers, on the order of 10 to 15 kcal mol(-1), and form activated open-chain C(7)H(5) species that can isomerize to the fulvenallenyl radical with the highest barrier still significantly below the entrance channel energy. Higher-energy pathways are available leading to other C(7)H(5) isomers and to a number of C(7)H(4) species + H. Rate constants in the large multiple-well (15) multiple-channel (30) chemically activated system are obtained from a stochastic solution of the one-dimensional master equation, with RRKM theory for microcanonical rate constants. The dominant products of the C(4)H(2) + C(3)H(3) reaction at combustion-relevant temperatures and pressures are i-C(5)H(3) + C(2)H(2) and CH(2)CCHCCCCH + H, along with several quenched C(7)H(5) intermediate species below 1500 K. The major products in the n-C(5)H(3) + C(2)H(2) reaction are i-C(5)H(3) + C(2)H(2) and a number of C(7)H(4) species + H, with C(7)H(5) radical stabilization at lower temperatures. The i-C(5)H(3) + C(2)H(2) reaction predominantly leads to C(7)H(4) + H and to stabilized C(7)H(5) products. The title reactions may play an important role in polycyclic aromatic hydrocarbon (PAH) formation in combustion systems. The C(7)H(5) potential energy surface developed here also provides insight into several other important reacting gas-phase systems relevant to combustion and astrochemistry, including C(2)H + the C(3)H(4) isomers propyne and allene, benzyne + CH, benzene + C((3)P), and C(7)H(5) radical decomposition, for which some preliminary analysis is presented. © The Owner Societies 2011
This study uses computational chemistry and statistical reaction rate theory to i nvestigate the chemically activated reaction of diacetylene (n class="Chemical">butadiyne ,
C(4)H (2)) with the
propargyl radical (C˙H(2)CCH) and the reaction of
acetylene (
C(2)H (2)) with the i-C(5)H(3) (CH(2)CCCC˙H) and
n -C(5)H(3) (CHCC˙HCCH) radicals. A detailed G3SX-level
C(7)H (5) energy surface demonstrates that the C(3)H(3) +
C(4)H (2) and C(5)H(3) +
C(2)H (2) addition reactions proceed with moderate barriers, on the order of 10 to 15 kcal mol(-1), and form activated open-chain
C(7)H (5) species that can isomerize to the fulvenallenyl radical with the highest barrier still significantly below the entrance channel energy. Higher-energy pathways are available leading to other
C(7)H (5) isomers and to a number of
C(7)H (4) species + H. Rate constants in the large multiple-well (15) multiple-channel (30) chemically activated system are obtained from a stochastic solution of the one-dimensional master equation, with RRKM theory for microcanonical rate constants. The dominant products of the
C(4)H (2) + C(3)H(3) reaction at combustion-relevant temperatures and pressures are i-C(5)H(3) +
C(2)H (2) and CH(2)CCHCCCCH + H, along with several quenched
C(7)H (5) intermediate species below 1500 K. The major products in the
n -C(5)H(3) +
C(2)H (2) reaction are i-C(5)H(3) +
C(2)H (2) and a number of
C(7)H (4) species + H, with
C(7)H (5) radical stabilization at lower temperatures. The i-C(5)H(3) +
C(2)H (2) reaction predominantly leads to
C(7)H (4) + H and to stabilized
C(7)H (5) products. The title reactions may play an important role in
polycyclic aromatic hydrocarbon (
PAH ) formation in combustion systems. The
C(7)H (5) potential energy surface developed here also provides insight into several other important reacting gas-phase systems relevant to combustion and astrochemistry, including
C(2)H + the
C(3)H(4) isomers
propyne and
allene ,
benzyne + CH,
benzene + C(
(3)P) , and
C(7)H (5) radical decomposition, for which some preliminary analysis is presented. © The Owner Societies 2011
Entities: Chemical
Disease
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Year: 2011
PMID: 21465038 DOI: 10.1039/c1cp20112c
Source DB: PubMed Journal: Phys Chem Chem Phys ISSN: 1463-9076 Impact factor: 3.676