6533b86efe1ef96bd12cb661

RESEARCH PRODUCT

Quantum dynamical study of the O(1D) + CH4→ CH3+ OH atmospheric reaction

Miguel GonzálezMohamed JorfiD. Ben AbdallahR. Ben BouchritNejm-eddine JaidaneBéatrice Bussery-honvaultPascal Honvault

subject

ChemistryScatteringAb initioGeneral Physics and AstronomyAtmospheric temperature rangeMolecular physicsAb initio quantum chemistry methodsTotal angular momentum quantum numberAtmospheric chemistryPotential energy surfacePhysics::Chemical PhysicsPhysical and Theoretical ChemistryAtomic physicsQuantum

description

Time independent quantum mechanical (TIQM) scattering calculations have been carried out for the O((1)D) + CH4(X(1)A1) → CH3(X(2)A2″) + OH(X(2)Π) atmospheric reaction, using an ab initio ground potential energy surface where the CH3 group is described as a pseudo-atom. Total and state-to-state reaction probabilities for a total angular momentum J = 0 have been determined for collision energies up to 0.5 eV. The vibrational and rotational state OH product distributions show no specific behavior. The rate coefficient has been calculated by means of the J-shifting approach in the 10-500 K temperature range and slightly depends on T at ordinary temperatures (as expected for a barrierless reaction). Quantum effects do not influence the vibrational populations and rate coefficient in an important way, and a rather good agreement has been found between the TIQM results and the quasiclassical trajectory and experimental ones. This reinforces somewhat the reliability of the pseudo-triatomic approach under the reaction conditions explored.

yearjournalcountryeditionlanguage
2014-06-28The Journal of Chemical Physics
https://doi.org/10.1063/1.4885276