Publications

Klippenstein, Stephen J.; Senosiain, Juan P.; Miller, James A.

Abstract not provided.

Proposed for publication in Journal of Physical Chemistry A.

Senosiain, Juan P.; Klippenstein, Stephen J.; Miller, James A.

The potential energy surface for the reaction between OH and acetylene has been calculated using the RQCISD(T) method and extrapolated to the complete basis-set limit. Rate coefficients were determined for a wide range of temperatures and pressures, based on this surface and the solution of the one-dimensional and two-dimensional master equations. With a small adjustment to the association energy barrier (1.1 kcal/mol), agreement with experiments is good, considering the discrepancies in such data. The rate coefficient for direct hydrogen abstraction is significantly smaller than that commonly used in combustion models. Also in contrast to previous models, ketene + H is found to be the main product at normal combustion conditions. At low temperatures and high pressures, stabilization of the C{sub 2}H{sub 2}OH adduct is the dominant process. Rate coefficient expressions for use in modeling are provided.

Proposed for publication in Nature.

McIlroy, Andrew M.; Hansen, Nils H.; Miller, James A.; Klippenstein, Stephen J.; Senosiain, Juan P.

Abstract not provided.