Three-Body Collisions Driving the Ion-Molecule Reaction C + H at Low Temperatures

Overview

Journal J Phys Chem A

Publisher American Chemical Society

Specialty Chemistry

Date 2023 Jun 2

PMID 37265338

Authors

Christine Lochmann

Markus Notzold

Robert Wild

Mauro Satta

Ersin Yurtsever

Francesco A Gianturco

Roland Wester

Affiliations

Soon will be listed here.

Abstract

We report on the three-body reaction rate of C with H producing CH studied in a cryogenic 16-pole radio frequency ion trap. The reaction was measured in the temperature range from 10 to 28 K, where it was found to only take place via three-body collisions. The experimentally determined termolecular rate coefficient follows the form of with = 20 K, where = 8.2(3) × 10 cm/s and = -0.82(12) denotes the temperature dependence. We additionally performed accurate calculations of the forces between the interacting partners and carried out variational transition state theory calculations, including tunneling through the barrier along the minimum energy path. We show that, while a simple classical model can generally predict the temperature dependence, the variational transition state theoretical calculations, including accurate quantum interactions, can explain the dominance of three-body effects in the molecular reaction mechanism and can reproduce the experimentally determined reaction coefficients, linking them to a temperature-dependent coupling parameter for energy dissipation within the transition complex.

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