Pyrolysis of <i>n</i>-Butylbenzene at Various Pressures: Influence of Long Side-Chain Structure on Alkylbenzene Pyrolysis

Zhang, Yan; Cao, Chuangchuang; Li, Yuyang; Yuan, Wenhao; Yang, Xiaoyuan; Yang, Jiuzhong; Qi, Fei; Huang, Tzu-Ping; Lee, Yin‐Yu

doi:10.1021/acs.energyfuels.7b02855

Cited by 49 publications

(25 citation statements)

References 50 publications

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“…As a result, tetralin is almost totally consumed by bimolecular reactions via the attack of small radicals, while the unimolecular decomposition reactions show only minor contributions to the consumption of tetralin in both the lean and rich flames. This is similar to the case in the pyrolysis of tetralin, 14 which indicates that tetralin has quite different decomposition characteristics to alkylbenzenes like ethylbenzene, 29,40 n ‐propylbenzene, 33,41 and n ‐butylbenzene 42,43 . Among the unimolecular decomposition reactions, the H 2 ‐elimination reaction producing H2A2 and H 2 and the simultaneous cleavage of two benzylic CC bonds producing o ‐xylylene (o‐C 8 H 8 ) and C 2 H 4 are the dominant ones in both the lean and rich flames, while the total contribution of unimolecular decomposition reactions to the consumption of tetralin is enhanced in the rich flame, as shown in Figure 5.…”

Section: Resultssupporting

confidence: 69%

“…This is similar to the case in the pyrolysis of tetralin, 14 which indicates that tetralin has quite different decomposition characteristics to alkylbenzenes like ethylbenzene, 29,40 n-propylbenzene, 33,41 and n-butylbenzene. 42,43 Among the unimolecular decomposition reactions, the H 2 -elimination reaction producing H2A2 and H 2 and the simultaneous cleavage of two benzylic C C bonds producing o-xylylene (o-C 8 H 8 ) and C 2 H 4 are the dominant ones in both the lean and rich flames, while the total contribution of unimolecular decomposition reactions to the consumption of tetralin is enhanced in the rich flame, as shown in Figure 5. It can be found that both of the two dominant unimolecular decomposition reactions are not producing any radicals, indicating the negligible roles of the unimolecular decomposition reactions in the chain reaction system of tetralin flames.…”

Section: Fuel Decomposition and Smaller Products Formationmentioning

confidence: 99%

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Unraveling chemical structure of laminar premixed tetralin flames at low pressure with photoionization mass spectrometry and kinetic modeling

Zou

Yuan

et al. 2020

Int J of Chemical Kinetics

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This work reports an investigation on laminar premixed flames of tetralin at 30 Torr and equivalence ratios of 0.7 and 1.7. Measurements of the chemical structure including identification and mole fraction measurements of free radicals, isomers, and polycyclic aromatic hydrocarbons (PAHs) were performed using synchrotron vacuum ultraviolet photoionization mass spectrometry (SVUV-PIMS). A kinetic model with 296 species and 1 577 reactions was developed and validated against the flame chemical structure data measured in this work. Modeling analysis reveals the key reaction pathways in tetralin decomposition and PAHs formation. The H-atom abstraction reactions by H, O, and OH are found to control the consumption of tetralin in the lean flame, while those by H play the dominant role in the rich flame. Indene and naphthalene have very high concentration levels in the rich tetralin flame due to the existence of direct formation pathways from the decomposition of tetralin. The two bicyclic PAHs and their radicals play significant roles in the PAHs growth process of tetralin combustion, which results in the high sooting tendency of tetralin compared to those of alkylbenzenes with smaller or same carbon atom numbers.

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Section: Resultssupporting

confidence: 69%

Section: Fuel Decomposition and Smaller Products Formationmentioning

confidence: 99%

Unraveling chemical structure of laminar premixed tetralin flames at low pressure with photoionization mass spectrometry and kinetic modeling

Zou

Yuan

et al. 2020

Int J of Chemical Kinetics

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“…The present work first investigated the temperature, pressure and reaction time dependencies of the yields of CH4, C6H6 and C7H8, based on detailed kinetic models [23][24][25]. Three C10 fuels, n-decane, decalin and n-butylbenzene, were selected to represent paraffinic, naphthenic and aromatic fuel classes.…”

Section: Ch4 and The Ratio Of [C6h6]/([c6h6]+[c7h8]mentioning

confidence: 99%

“…were initially collected from experiments on the pyrolysis of 44 neat fuels, covering wide temperature, pressure and reaction time conditions. They were obtained in different labs with various experimental apparatus, such as shock tubes [26][27][28][29], flow reactors [22,25,30,31] and jet-stirred reactors (JSR) [32,33]. All of these collected speciation data included experimental uncertainties, so they were evaluated to establish consistency across different datasets.…”

Section: Ch4 and The Ratio Of [C6h6]/([c6h6]+[c7h8]mentioning

confidence: 99%

A functional-group-based approach to modeling real-fuel combustion chemistry – I: Prediction of stoichiometric parameters for lumped pyrolysis reactions

Zhang

Yalamanchi

Sarathy

2021

Combustion and Flame

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“…The flow reactor pyrolysis experiments were performed at the National Synchrotron Radiation Laboratory. Detailed introduction to the beamline and the flow reactor apparatus have been introduced elsewhere [16][17][18][19]. o-Xylene (purchased from Sinopharm Chemical Reagent Limited Co., Shanghai, China, with purity≥99%) was gasified in a home-made vaporizer.…”

Section: Flow Reactor Pyrolysismentioning

confidence: 99%

Exploring pyrolysis and oxidation chemistry of o-xylene at various pressures with special concerns on PAH formation

Yuan

Zhao²,

Gaïl³

et al. 2021

Combustion and Flame

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This work reports an experimental and kinetic modelling investigation on flow reactor pyrolysis and jet-stirred reactor oxidation of o-xylene. The flow reactor pyrolysis experiments were conducted over 1050-1600 K at 0.04 and 1.0 atm. Key products related to fuel decomposition such as o-xylyl radical, o-xylylene, benzocyclobutene and styrene, as well as polycyclic aromatic hydrocarbons (PAHs), were detected by using synchrotron vacuum ultraviolet photoionization mass spectrometry. The jet-stirred reactor oxidation experiments were performed at 10 atm, 800-1200 K, a residence time of 0.5 s and equivalence ratios of 0.5, 1.0 and 2.0. Speciation were conducted by using gas chromatography and Fourier transform infrared spectrometry. A kinetic model of o-xylene was developed from our previous models of aromatic fuels and validated against both present data and experimental data in literature. Styrene is observed as the dominant product in the pyrolysis of oxylene and it is mainly produced from the isomerization of o-xylylene directly or via benzocyclobutene as an intermediate species. C9 PAHs (indenyl, indene and indane), phenanthrene and its methyl derivatives were observed as the abundantly produced bicyclic and tricyclic PAHs. The main formation pathways of bicyclic and tricyclic PAHs are found to be different at low and atmospheric pressures, depending on the major precursors produced. Particularly, the self-combination reactions of o-xylyl and the addition reaction of o-xylyl with benzyl and subsequent stepwise H-loss/cyclization reactions are found to be the main sources of methylphenanthrene and dimethylphenanthrene. In the JSR oxidation of o-xylene, toluene and benzene were observed as the abundantly produced aromatic products, while o-methylbenzaldehyde was among the most abundantly produced oxygenated aromatics. Modelling analysis reveals that o-xylyl radical is also the dominant fuel consumption product. Its consumption mainly proceeds through the oxidation by HO2 and finally produces omethylbenzaldehyde. Further decomposition reactions of o-methylbenzaldehyde contribute to the formation of other major oxygenated aromatics such as cresol and benzofuran. Indene and naphthalene were also observed in the oxidation of o-xylene, which are mainly produced from the stepwise Hloss/cyclization reaction sequence of o-methylethylbenzene and decomposition of dibenzofuran, respectively.

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Pyrolysis of n-Butylbenzene at Various Pressures: Influence of Long Side-Chain Structure on Alkylbenzene Pyrolysis

Cited by 49 publications

References 50 publications

Unraveling chemical structure of laminar premixed tetralin flames at low pressure with photoionization mass spectrometry and kinetic modeling

Unraveling chemical structure of laminar premixed tetralin flames at low pressure with photoionization mass spectrometry and kinetic modeling

A functional-group-based approach to modeling real-fuel combustion chemistry – I: Prediction of stoichiometric parameters for lumped pyrolysis reactions

Exploring pyrolysis and oxidation chemistry of o-xylene at various pressures with special concerns on PAH formation

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