Mahdi Taghikhani scite author profile

The hydrogen abstraction reaction of the OH radical with CH 3 CHF 2 (HFC152-a) has been studied theoretically over a wide temperature range, 200-3000 K. Two different reactive sites of the molecule, CH 3 and CHF 2 groups have been investigated precisely, and results confirm that CHF 2 position of the molecule is a highly reactive site. In this study, three recently developed hybrid density functional theories, namely, MPWB1K, MPW1B95, and MPW1K, are used. The MPWB1K/6-31+G(d,p) method gives the best result for kinetic calculations, including barrier heights, reaction path information and geometry of transition state structures and other stationary points. To refine the barrier height of each channel, a single point energy calculation was performed in MPWB1K/MG3S method. The obtained rate constants by dual level direct dynamics with the interpolated single point energy method (VTST-ISPE) using DFT quantum computational methods, are consistent with available experimental data. The canonical variational transition state theory (CVT) with the zero-curvature and also the small-curvature tunneling correction methods is used to calculate the rate constants. Over the temperature range 200-3000 K, the variation effect, tunneling contribution, branching ratio of each channel are calculated. The rate constants and their temperature dependency in the form of a fitted threeparameter Arrhenius expression are k 1 (T) ) 2.00 × 10 -19 (T) 2.24 exp(-1273/T), k 2 (T) ) 1.95 × 10 -19 (T) 2.46 exp(-2374/T), and k(T) ) 3.13 × 10 -19 (T) 2.47 exp(-1694/T) cm 3 molecule -1 s -1 . For the H abstraction from the CHF 2 group, a nonclassical reflection effect is detected as a dominant quantum effect.

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Theoretical investigation of imidazolium based ionic liquid/alcohol mixture: a molecular dynamic simulation

Jahangiri

Taghikhani

Behnejad

et al. 2008

Molecular Physics

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In this work, molecular dynamic simulation of the mixture of imidazolium based ionic liquids with alcohols is implemented in order to investigate mixing excess properties and some structural and physical properties of the mixture. Excess volumes and enthalpies are evaluated for 11 different mole fractions of ionic liquids at each 0.1, in the range of 0 to 1. Radial distribution function, cohesive energy density, potential of mean force, solvation energy, and diffusion coefficient are reported and analysed. The effects of the cationic alkyl chain length, in comparison with changes of the anions, on these properties are reported. Results reveal that the methanol molecule participates with its hydrophilic characteristics in the mixing process and tends to aggregate around anion part of the ionic liquids, especially in the case of Cl.

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Theoretical Investigation of the Hydrogen Abstraction Reaction of the OH Radical with CH₂FCH₂F (HFC-152): A Dual-Level Direct Dynamics Study

Taghikhani

Parsafar

2007

J. Phys. Chem. A

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The hydrogen abstraction reaction of the OH radical with CH(2)FCH(2)F (HFC-152) is studied theoretically over the 150-3000 K temperature range. In this study, the two most recently developed hybrid density functional theories, namely, BB1K and MPWB1K, are applied, and their efficiency in reaction dynamics calculation is discussed. The BB1K/6-31+G(d,p) method gives the best result for the potential energy surface (PES) calculations, including barrier heights, reaction path information (the first and second derivatives of PES), geometry of transition state structures, and even weak hydrogen bond orientations. The rate constants were obtained by the dual-level direct dynamics with the interpolated single-point energy method (VTST-ISPE) using the BB1K/MG3S//BB1K/6-31+G(d,p) quantum model. The canonical variational transition state theory (CVT) with the small-curvature tunneling correction methods are used to calculate the rate constants in comparison to the experimental data. The total rate constant and its temperature dependency in the form of a fitted three-parameter Arrhenius expression is k(T) = 5.4 x 10(-13)(T/298)3.13 exp{-322/T} cm3 molecule(-1) s(-1). A significant variational effect, which is not common generally for hydrogen-transfer reactions, is reported and analyzed.

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Proton exchange in acid–base complexes induced by reaction coordinates with heavy atom motions

Alavi

Taghikhani

2012

Chemical Physics

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