Thermal Rate Constants for the O(<sup>3</sup>P) + HBr and O(<sup>3</sup>P) + DBr Reactions: Transition-State Theory and Quantum Mechanical Calculations

Oliveira-Filho, Antonio G. S. de; Ornellas, Fernando R.; Peterson, Kirk A.; Mielke, Steven L.

doi:10.1021/jp4090684

Cited by 6 publications

(10 citation statements)

References 92 publications

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“…However, the modified Clary potential yields a reversed division of energy between translation and rotation when compared to our results and to Persky’s observations . The energy disposal in the OH + HBr reaction is very similar to that in the O( 3 P) + HBr reaction, which has an early transition state with a bending frequency of 213 cm –1 and a barrier height of 5.01 kcal mol –1 and positive activation energy. , The fractional energy release for the O + HBr reaction in vibration and rotation was measured to be 0.51 and 0.24, respectively. , This fact suggests that the energy disposal in the OH + HBr reaction has two major determinant factors, the kinematic constraints imposed by the mass combination of reactants and products, as in many other abstractions of light atoms between two heavy atoms (H + LH′ → HL + H′), that lead to the characteristic large release to product vibration energy and the low bending frequencies at the transition state that relate to the rotational excitation of the products.…”

Section: Results and Discussionsupporting

confidence: 78%

Energy Disposal and Thermal Rate Constants for the OH + HBr and OH + DBr Reactions: Quasiclassical Trajectory Calculations on an Accurate Potential Energy Surface

2014

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We report reaction cross sections, energy disposal, and rate constants for the OH + HBr → Br + H2O and OH + DBr → Br + HDO reactions from quasiclassical trajectory calculations using an ab initio potential energy surface [ de Oliveira-Filho , A. G. S. ; Ornellas , F. R. ; Bowman , J. M. J. Phys. Chem. Lett. 2014 , 5 , 706 - 712 ]. Comparison with available experiments are made and generally show good agreement.

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Section: Results and Discussionsupporting

confidence: 78%

Energy Disposal and Thermal Rate Constants for the OH + HBr and OH + DBr Reactions: Quasiclassical Trajectory Calculations on an Accurate Potential Energy Surface

2014

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“…The rate constant used in our modeling work for HBr + O → Br + OH was taken from Nava et al and has been utilized by many others in modeling work. We have revaluated this rate expression using all the experimental values by Nicovich and Wine , Nava et al , Singleton and Cvetanovic , and Brown and Smith and also taking into consideration the computational values by de Oliveira‐Filho et al and Broida et al . Fits to the experimental data and the computed values yielded nonlinear Arrhenius expressions ( T b ) with b ranging from 1.92 to 2.53 and activation energies E = 5.6–7.3 kJ/mol.…”

Section: Appendixmentioning

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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“…Furthermore, the recent progress in the development of linear-scaling coupled-cluster methods has pushed the limits of application to quite large molecules. − To summarize, the situation for closed-shell molecules is such that the well-known CCSD(T) method (CC theory with singles, doubles, and perturbative triples clusters) used with sufficiently large basis sets is believed to provide accurate thermochemical data within 1 kcal mol –1 accuracy. More advanced methods that, in particular, take care of correlation effects beyond CCSD(T) by additive schemes can even reach the 1 kJ mol –1 regime and may even be used to challenge the validity of experimentally derived results. − Examples are the high accuracy extrapolated ab initio thermochemistry approach (HEAT), the Weizmann-4 protocol (W4 , ), focal point analysis (FPA − ), the Feller–Peterson–Dixon method (FPD ,, ), and the correlation consistent composite approach (ccCA , ) and its multireference version (MR-ccCA).…”

Section: Introductionmentioning

confidence: 99%

How To Arrive at Accurate Benchmark Values for Transition Metal Compounds: Computation or Experiment?

Aoto

Batista

Köhn

et al. 2017

J. Chem. Theory Comput.

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With the objective of analyzing which kind of reference data is appropriate for benchmarking quantum chemical approaches for transition metal compounds, we present the following, (a) a collection of 60 transition metal diatomic molecules for which experimentally derived dissociation energies, equilibrium distances, and harmonic vibrational frequencies are known and (b) a composite computational approach based on coupled-cluster theory with basis set extrapolation, inclusion of core-valence correlation, and corrections for relativistic and multireference effects. The latter correction was obtained from internally contracted multireference coupled-cluster (icMRCC) theory. This composite approach has been used to obtain the dissociation energies and spectroscopic constants for the 60 molecules in our data set. In accordance with previous studies on a subset of molecules, we find that multireference corrections are rather small in many cases and CCSD(T) can provide accurate reference values, if the complete basis set limit is explored. In addition, the multireference correction improves the results in cases where CCSD(T) is not a good approximation. For a few cases, however, strong deviations from experiment persist, which cannot be explained by the remaining error in the computational approach. We suggest that these experimentally derived values require careful revision. This also shows that reliable reference values for benchmarking approximate computational methods are not always easily accessible via experiment and accurate computations may provide an alternative way to access them. In order to assess how the choice of reference data affects benchmark studies, we tested 10 DFT functionals for the molecules in the present data set against experimental and calculated reference values. Despite the differences between these two sets of reference values, we found that the ranking of the relative performance of the DFT functionals is nearly independent of the chosen reference.

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Thermal Rate Constants for the O(³P) + HBr and O(³P) + DBr Reactions: Transition-State Theory and Quantum Mechanical Calculations

Cited by 6 publications

References 92 publications

Energy Disposal and Thermal Rate Constants for the OH + HBr and OH + DBr Reactions: Quasiclassical Trajectory Calculations on an Accurate Potential Energy Surface

Energy Disposal and Thermal Rate Constants for the OH + HBr and OH + DBr Reactions: Quasiclassical Trajectory Calculations on an Accurate Potential Energy Surface

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

How To Arrive at Accurate Benchmark Values for Transition Metal Compounds: Computation or Experiment?

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Thermal Rate Constants for the O(3P) + HBr and O(3P) + DBr Reactions: Transition-State Theory and Quantum Mechanical Calculations

Cited by 6 publications

References 92 publications

Energy Disposal and Thermal Rate Constants for the OH + HBr and OH + DBr Reactions: Quasiclassical Trajectory Calculations on an Accurate Potential Energy Surface

Energy Disposal and Thermal Rate Constants for the OH + HBr and OH + DBr Reactions: Quasiclassical Trajectory Calculations on an Accurate Potential Energy Surface

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

How To Arrive at Accurate Benchmark Values for Transition Metal Compounds: Computation or Experiment?

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Thermal Rate Constants for the O(³P) + HBr and O(³P) + DBr Reactions: Transition-State Theory and Quantum Mechanical Calculations