An absolute proton affinity scale in the ∼130–140 kcal mol−1 range

Abstract

The dependences on temperature of the rate coefficients for the endothermic proton transfer reactions of HBr⁺ with CO₂ and CH₄ have been obtained in a variable‐temperature selected ion flow tube. The measurements have been used to determine the 300 K proton affinity of CO₂, P.A.(CO₂), =128.5±1.0 kcal mol⁻¹, utilizing the literature value of P.A.(Br)=131.8 kcal mol⁻¹, obtained from the dissociation energy of HBr⁺, as a primary standard. The proton affinity difference between CO₂ and CH₄ has been substantiated by equilibrium constant measurements as a function of temperature for proton transfer between CO₂ and CH₄. Similar equilibrium constant measurements have been used to determine the proton affinities of HCl, N₂ O, HBr, and CO, giving a proton affinity ladder ordered (in kcal mol⁻¹) as CO(141.4), HBr(138.8), N₂ O(137.3), HCl(133.0), Br(131.8), CH₄ (130.0), and CO₂(128.5). Proton affinities have also been determined for Br₂(140.0), NO(127.0), and CF₄(126.5), the last two values being obtained from selected ion flow drift tube measurements. An upper limit to P.A.(SF₆) of 127 kcal mol⁻¹ has been inferred from the instability of SF₆ H⁺ towards dissociation into SF⁺₅ and HF.