Reaction Dynamics of Phenyl Radicals in Extreme Environments: A Crossed Molecular Beam Study

Gu, Xia; Kaiser, Ralf I.

doi:10.1021/ar8001365

Cited by 63 publications

(72 citation statements)

References 52 publications

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“…16 Pulsed ground state silicon atoms were produced in the primary source by laser ablation of a silicon rod at 266 nm by focusing a few millijoules per pulse on the rotating silicon rod. The ablated species were seeded in neat hydrogen carrier gas ͑Matheson; 99.9999%͒ at 3040 torr backing pressure released by a Proch-Trickl pulsed valve operated at pulse widths of 80 s and Ϫ400 V. After passing a skimmer, a four-slot chopper wheel mounted after the ablation zone selected a part out of the seeded ground state silicon atom beam with a peak velocity of 2329Ϯ 38 m s −1 and a speed ratio of 5.5Ϯ 0.9.…”

Section: Methodsmentioning

confidence: 99%

Chemical dynamics of the formation of the ethynylsilylidyne radical (SiCCH(X Π2)) in the crossed beam reaction of ground state silicon atoms (Si(P3)) with acetylene (C2H2(X ∑g+1))

Kaiser

2009

The Journal of Chemical Physics

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The reaction dynamics of ground state silicon atoms ͑Si͑ 3 P͒͒ with the acetylene molecule ͑C 2 H 2 ͑X 1 ͚ g + ͒͒ were investigated at a collision energy of 101.6Ϯ 1.6 kJ mol −1 under single collision conditions in a crossed molecular beam machine. We found that the reaction dynamics proceeded via an addition of the silicon atom to the -electrons of the acetylene molecule at a single carbon atom forming a C s symmetric SiC 2 H 2 ͑X 3 AЉ͒ intermediate. The latter either emitted a hydrogen atom leading to the linear SiCCH͑X 2 ⌸͒ product or underwent a hydrogen migration to the SiCCH 2 ͑X 3 A 2 ͒ isomer prior to the decomposition of the latter to SiCCH͑X 2 ⌸͒ plus atomic hydrogen. The overall reaction to form the SiCCH͑X 2 ⌸͒ plus atomic hydrogen products was determined to be highly endoergic by 84Ϯ 6 kJ mol −1 . No evidence of a molecular hydrogen elimination channel was found at this collision energy. Our study predicts that this endoergic neutral-neutral reaction can lead to the formation of an organosilicon transient species, i.e., the linear SiCCH͑X 2 ⌸͒ radical, in high-temperature environments like in the circumstellar envelope of the carbon star IRC+ 10 216, where temperatures of a few 1000 K exist close to the central star.

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Section: Methodsmentioning

confidence: 99%

Chemical dynamics of the formation of the ethynylsilylidyne radical (SiCCH(X Π2)) in the crossed beam reaction of ground state silicon atoms (Si(P3)) with acetylene (C2H2(X ∑g+1))

Kaiser

2009

The Journal of Chemical Physics

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“…[11][12][13] In detail, PAHs have been suggested to be formed via hydrogen abstractionacetylene addition (HACA) sequences 14 or via phenyl addition -cyclization pathways (PAC). 15 Alternative pathways have been investigated via kinetic studies [16][17][18][19] and crossed beam experiments [20][21][22][23] of phenyl radicals with unsaturated hydrocarbons. Very recently, indane has been identified as one of the products in a low-pressure premixed toluene/oxygen/ argon fuel rich flames by .…”

Section: Introductionmentioning

confidence: 99%

A VUV Photoionization Study of the Combustion-Relevant Reaction of the Phenyl Radical (C₆H₅) with Propylene (C₃H₆) in a High Temperature Chemical Reactor

et al. 2012

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We studied the reaction of phenyl radicals (C 6 H 5 ) with propylene (C 3 H 6 ) exploiting a high temperature chemical reactor under combustion-like conditions (300 Torr, 1,200-1,500 K). The reaction products were probed in a supersonic beam by utilizing tunable vacuum ultraviolet (VUV) radiation from the Advanced Light Source and recording the photoionization efficiency (PIE) curves at mass-to-charge ratios of m/z = 118 (C 9 H 10 + ) and m/z = 104 (C 8 H 8 + ). Our results suggest that the methyl and atomic hydrogen losses are the two major reaction pathways with branching ratios of 86 ± 10 % and 14 ± 10 %. The isomer distributions were probed by fitting the recorded PIE curves with a linear combination of the PIE curves of the individual C 9 H 10 and C 8 H 8 isomers. Styrene (C 6 H 5 C 2 H 3 ) was found to be the exclusive product contributing to m/z = 104 (C 8 H 8 + ), whereas 3-phenylpropene, cis-1-phenylpropene, and 2-phenylpropene with branching ratios of 96 ± 4 %, 3 ± 3 %, and 1 ± 1 % could account for signal at m/z = 118 (C 9 H 10 + ).Although searched for carefully, no evidence of the bicyclic indane molecule could be provided.The reaction mechanisms and branching ratios are explained in terms of electronic structure calculations nicely agreeing with a recent crossed molecular beam study on this system.

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“…116 The apparatus consists of two source chambers at a crossing angle of 90 , a stainless steel scattering chamber, and an ultrahigh-vacuum tight, rotatable, differentially pumped quadrupole mass spectrometric (QMS) detector that can be pumped down to a vacuum in the high 10 À13 Torr range ( Fig. 11.1).…”

Section: The Crossed Beam Machinementioning

confidence: 99%

“…116 Specific details and the methodology of the crossed beam approach are given for the reactions of phenyl radicals with acetylene, ethylene, and benzene as simplest representatives of unsaturated molecules containing triplet, double, and "aromatic" bonds, respectively. Then, the conclusions are transferred to the methylacetylene, allene, and propylene reactants to elucidate generalized concepts on the chemical dynamics, reactivity, and reaction mechanisms of the reactions of phenyl radicals with unsaturated hydrocarbons in extreme environments.…”

Section: Reactions Of Phenyl Radicalsmentioning

confidence: 99%

Reaction Dynamics of Phenyl Radicals in Extreme Environments: A Crossed Molecular Beam Study

Cited by 63 publications

References 52 publications

Chemical dynamics of the formation of the ethynylsilylidyne radical (SiCCH(X Π2)) in the crossed beam reaction of ground state silicon atoms (Si(P3)) with acetylene (C2H2(X ∑g+1))

Chemical dynamics of the formation of the ethynylsilylidyne radical (SiCCH(X Π2)) in the crossed beam reaction of ground state silicon atoms (Si(P3)) with acetylene (C2H2(X ∑g+1))

A VUV Photoionization Study of the Combustion-Relevant Reaction of the Phenyl Radical (C₆H₅) with Propylene (C₃H₆) in a High Temperature Chemical Reactor

Reaction Dynamics of Carbon‐Centered Radicals in Extreme Environments Studied by the Crossed Molecular Beam Technique

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Reaction Dynamics of Phenyl Radicals in Extreme Environments: A Crossed Molecular Beam Study

Cited by 63 publications

References 52 publications

Chemical dynamics of the formation of the ethynylsilylidyne radical (SiCCH(X Π2)) in the crossed beam reaction of ground state silicon atoms (Si(P3)) with acetylene (C2H2(X ∑g+1))

Chemical dynamics of the formation of the ethynylsilylidyne radical (SiCCH(X Π2)) in the crossed beam reaction of ground state silicon atoms (Si(P3)) with acetylene (C2H2(X ∑g+1))

A VUV Photoionization Study of the Combustion-Relevant Reaction of the Phenyl Radical (C6H5) with Propylene (C3H6) in a High Temperature Chemical Reactor

Reaction Dynamics of Carbon‐Centered Radicals in Extreme Environments Studied by the Crossed Molecular Beam Technique

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A VUV Photoionization Study of the Combustion-Relevant Reaction of the Phenyl Radical (C₆H₅) with Propylene (C₃H₆) in a High Temperature Chemical Reactor