Reaction Dynamics of CH<sub>3</sub>+ HBr → CH<sub>4</sub>+ Br at 150-1000 K

Ree, Jongbaik; Kim, Yoo Hang; Shin, Hyung Kyu

doi:10.5012/bkcs.2013.34.8.2473

Cited by 10 publications

(10 citation statements)

References 42 publications

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“…To provide a rate expression valid at flame temperatures, we fitted the low temperature (257-677 K) data of Seetula [125], Seakins et al [71], and Nicovich et al [197], while constraining the rate constants at 900-1100 K to be consistent with the relative temperature dependence calculated in the computational work of Ree et al [198]. Note that no rate expressions are given in that paper-we estimated the temperature dependence from the figures provided in the paper.…”

Section: Ch 3 + Hbr → Ch 4 + Brmentioning

confidence: 99%

A Chemical Kinetic Mechanism for 2‐Bromo‐3,3,3‐trifluoropropene (2‐BTP) Flame Inhibition

Burgess

Babushok

Linteris

et al. 2015

Int J of Chemical Kinetics

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In this work, we report a detailed chemical kinetic mechanism to describe the flame inhibition chemistry of the fire-suppressant 2-bromo-3,3,3-trifluoropropene (2-BTP), under consideration as a replacement for CF 3 Br. Under some conditions, the effectiveness of 2-BTP is similar to that of CF 3 Br; however, like other potential halon replacements, it failed an U.S. Federal Aviation Authority (FAA) qualifying test for its use in cargo bays. Large overpressures are observed in that test and indicate an exothermic reaction of the agent under those conditions. The kinetic model reported herein lays the groundwork to understand the seemingly conflicting behavior on a fundamental basis. The present mechanism and parameters are based on an extensive literature review supplemented with new quantum chemical calculations. The first part of the present article documents the information considered and provides traceability with respect to the reaction set, species thermochemistry, and kinetic parameters. In additional work, presented more fully elsewhere, we have combined the 2-BTP chemical kinetic mechanism developed here with several other submodels from the literature and then used the combined mechanism to simulate premixed flames over a range of fuel/air stoichiometries and agent loadings. Overall, the modeling results qualitatively predicted observations found in cupburner tests and FAA Aerosol Can Tests, including the extinguishing concentrations required and the lean-to-rich dependence of mixtures. With these data in hand, in a second phase of the present work, we perform a reaction path analysis of major species under several modeled conditions. This analysis leads to a qualitative understanding of the ability of 2-BTP to act as

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Section: Ch 3 + Hbr → Ch 4 + Brmentioning

confidence: 99%

A Chemical Kinetic Mechanism for 2‐Bromo‐3,3,3‐trifluoropropene (2‐BTP) Flame Inhibition

Burgess

Babushok

Linteris

et al. 2015

Int J of Chemical Kinetics

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“…The initial phases, 2 πδ i , are randomly sampled. The initial vibrational, rotational and collision energies are sampled using the vibrational and rotational distribution function, and the Maxwell–Boltzmann distribution, respectively . The initial value of the distance ρ is the impact parameter b , which is also randomly sampled.…”

Section: Methodsmentioning

confidence: 99%

“…Furthermore, the near temperature independence of the rate constants of reactions occurring between 138 and 216 K, observed by Sharkey et al, suggests that the effects of intermolecular attraction and H tunneling diminish above room temperature. We have recently developed a procedure for studying these effects, yielding a negative temperature dependence of the rate constants of radical‐polar molecular reactions . Because attractive forces are strong in radical‐polar molecule reactions, the reactants form a loosely bound complex, and the increase in reaction rates with decreasing temperature becomes significant at low temperatures.…”

Section: Introductionmentioning

confidence: 99%

Temperature Dependence of the Reaction HCl + OH → Cl + H₂O between 140 and 1100 K

Ree

Kim

2018

Bulletin Korean Chem Soc

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Temperature dependence of the molecule-radical reaction HCl + OH ! Cl + H 2 O at temperatures between 140 and 1100 K is studied using a quasiclassical trajectory method. Potential energy surfaces are formulated using pair-wise additive two-body, nonadditive three-body, and four-body analytic forms and long-range interactions. At temperatures above 300 K, the reaction occurs by direct collisions and the calculated rate constant fits the Arrhenius equation k dir = 4.85 × 10 −12 exp.(−631 AE 10/T) cm 3 /molecule/s. At temperatures below 300 K, the reaction is driven by an attractive potential and occurs through the formation of a ClH…OH collision complex, which is sufficiently long-lived to enhance quantum mechanical tunneling of the H atoms. The sum of the direct and complex-mode reaction rates effectively describes the reaction occurring at temperatures in the 140-1100 K temperature range.

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“…The formation of HBr via H+Br collision requires a threebody interaction and thus is most efficient on grain surfaces (e.g. Ree et al 2004).…”

Section: Interstellar Chemistry Of Brmentioning

confidence: 99%

Interstellar bromine abundance is consistent with cometary ices from Rosetta

Ligterink

Kama

2018

A&A

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Context. Cometary ices are formed during star and planet formation, and their molecular and elemental makeup can be related to the early solar system via the study of inter-and protostellar material. Aims. We set out to place the first observational constraints on the interstellar gas-phase abundance of bromine (Br). We further aim to compare the protostellar Br abundance with that measured by Rosetta in the ices of comet 67P/Churyumov-Gerasimenko. Methods. Archival Herschel data of Orion KL, Sgr B2(N), and NGC 6334I are examined for the presence of HBr and HBr + emission or absorption lines. A chemical network for modelling HBr in protostellar molecular gas is compiled to aid in the interpretation. Results. HBr and HBr + were not detected towards any of our targets. However, in the Orion KL Hot Core, our upper limit on HBr/H 2 O is a factor of ten below the ratio measured in comet 67P. This result is consistent with the chemical network prediction that HBr is not a dominant gas-phase Br carrier. Cometary HBr is likely predominantly formed in icy grain mantles which lock up nearly all elemental Br.

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Reaction Dynamics of CH₃+ HBr → CH₄+ Br at 150-1000 K

Cited by 10 publications

References 42 publications

A Chemical Kinetic Mechanism for 2‐Bromo‐3,3,3‐trifluoropropene (2‐BTP) Flame Inhibition

A Chemical Kinetic Mechanism for 2‐Bromo‐3,3,3‐trifluoropropene (2‐BTP) Flame Inhibition

Temperature Dependence of the Reaction HCl + OH → Cl + H₂O between 140 and 1100 K

Interstellar bromine abundance is consistent with cometary ices from Rosetta

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Reaction Dynamics of CH3+ HBr → CH4+ Br at 150-1000 K

Cited by 10 publications

References 42 publications

A Chemical Kinetic Mechanism for 2‐Bromo‐3,3,3‐trifluoropropene (2‐BTP) Flame Inhibition

A Chemical Kinetic Mechanism for 2‐Bromo‐3,3,3‐trifluoropropene (2‐BTP) Flame Inhibition

Temperature Dependence of the Reaction HCl + OH → Cl + H2O between 140 and 1100 K

Interstellar bromine abundance is consistent with cometary ices from Rosetta

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Reaction Dynamics of CH₃+ HBr → CH₄+ Br at 150-1000 K

Temperature Dependence of the Reaction HCl + OH → Cl + H₂O between 140 and 1100 K