Daniely V. V. Cardoso scite author profile

The structures, barrier heights, reaction enthalpies, and thermal rate constants of four reaction paths involving hydrogen abstraction and addition processes between O and CH3SH were computed using the Møller–Plesset perturbation theory at the second order level (MP2) and BB1K methods with the aug‐cc‐pV(T+d)Z basis set. A more accurate evaluation of the energetic of these reaction systems are performed by extrapolating the single point CCSD(T) energies to the complete basis set (CBS) limit approach using the BB1K and MP2/aug‐cc‐pV(T+d)Z geometries. The best estimates of the adiabatic barrier heights, determined using the CCSD(T)/CBS//(BB1K or MP2)/aug‐cc‐pV(T+d)Z method, are between 0.5 and 1.0 kcal mol−1 (R1, CH3S + OH), 5.3 and 5.5 kcal mol−1 (R2, CH2SH + OH), 1.3 and 2.3 kcal mol−1 (R3, CH3 + HSO), and 1.6 and 2.9 kcal mol−1 (R4, CH3SO + H). The thermal rate constants calculated using the dual‐level direct dynamics by variational transition state theory with interpolated single‐point energy corrections are in good agreement with experimental results. The calculated branching ratios at 300 K are 0.91:0.01:0.05:0.03 for the reactions paths R1–R4, respectively, which indicate that hydrogen abstraction from the SH group is the main reaction path. © 2012 Wiley Periodicals, Inc.

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The characterization of electronic defect states of single and double carbon vacancies in graphene sheets using molecular density functional theory

Pinheiro

Cardoso

Aquino

et al. 2019

Molecular Physics

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Erratum to “Thermochemistry and kinetics of the trans-N2H2+N reaction” [Chem. Phys. Lett. 557 (2013) 37–42]

Spada

Ferrão

Cardoso

et al. 2013

Chemical Physics Letters

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Thermochemical and Kinetics of CH₃SH + H Reactions: The Sensitivity of Coupling the Low and High-Level Methodologies

et al. 2017

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The reaction system formed by the methanethiol molecule (CHSH) and a hydrogen atom was studied via three elementary reactions, two hydrogen abstractions and the C-S bond cleavage (CHSH + H → CHS + H (R1); → CHSH + H (R2); → CH + HS (R3)). The stable structures were optimized with various methodologies of the density functional theory and the MP2 method. Two minimum energy paths for each elementary reaction were built using the BB1K and MP2 methodologies, and the electronic properties on the reactants, products, and saddle points were improved with coupled cluster theory with single, double, and connected triple excitations (CCSD(T)) calculations. The sensitivity of coupling the low and high-level methods to calculate the thermochemical and rate constants were analyzed. The thermal rate constants were obtained by means of the improved canonical variational theory (ICVT) and the tunneling corrections were included with the small curvature tunneling (SCT) approach. Our results are in agreement with the previous experimental measurements and the calculated branching ratio for R1:R2:R3 is equal to 0.96:0:0.04, with k = 9.64 × 10 cm molecule s at 298 K.

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Thermochemical and kinetics studies of the CH3SH+S (3P) hydrogen abstraction and insertion reactions

et al. 2014

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Sulfur-containing molecules have a significant impact on atmosphere and biosphere. In this work we studied, from the point of view of electronic structure and chemical kinetics methods, the elementary reactions between a methanethiol molecule and a sulfur atom leading to hydrogen abstraction C-S bond cleavage (CH(3)SH+S; R1:→ CH(3)S+SH; R2: → CH(2)SH+SH; R3:→ CH(3)+HS(2)). The geometrical structures of the reactants, products, and saddle points for the three reaction paths were optimized using the BB1K method with the aug-cc-pV(T+d)Z basis set. The thermochemical properties were improved using single point coupled-cluster (CCSD(T)) calculations on the BB1K geometries followed by extrapolation to the complete basis set (CBS) limit. This methodology was previously applied and has given accurate values of thermochemical and kinetics properties when compared to benchmark calculations and experimental data. For each reaction, the thermal rate constants were calculated using the improved canonical variational theory (ICVT) including the zero-curvature (ICVT/ZCT) and small-curvature (ICVT/SCT) tunneling corrections. For comparison, the overall ICVT/SCT reaction rate constant at 300 K obtained with single-point CCSD(T)/CBS calculations for the CH(3)SH+S reaction is approximately 1400 times lower than the isovalent CH(3)SH+O reaction, obtained with CVT/SCT. The reaction path involving the hydrogen abstraction from the thiol group is the most important reactive path in all temperatures.

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