Hybrid density functional theory with a specific reaction parameter: hydrogen abstraction reaction of trifluoromethane by the hydroxyl radical

Abstract

Potential energy surfaces are developed and tested for the OH + CHF3 → H2O + CF3 reaction. The objective is to obtain surfaces that give calculated rate constants comparable to the experimental ones. The potential energy surfaces are constructed using hybrid and hybrid meta density functional theory methods (mPW1PW91, B1B95, and mPW1B95) with specific reaction parameters in conjunction with the 6–31+ G(d,p) basis set. The rate constants are calculated over the temperature range 200–1,500 K using variational transition state theory with multidimensional tunneling contributions. The hybrid density functional theory methods with specific-reaction-parameter Hartree-Fock exchange contributions (32.8–34.8% for mPW1PW91, 34.2–36.0% for B1B95, and 37.8–39.7% for mPW1B95, respectively) provide accurate rate constants over an extended temperature range. The classical barrier height for the hydrogen abstraction reaction is determined to be 6.5–6.9 kcal/mol on these potential energy surfaces, and the best estimate value is 6.77 kcal/mol.