Inaccessibility of beta-hydride elimination from -OH functional groups in Wacker-type oxidation

INOR 648

John A Keith, johnk@wag.caltech.edu, Jonas Oxgaard, oxgaard@wag.caltech.edu, and William A Goddard III, wag@wag.caltech.edu. Materials and Process Simulation Center, California Institute of Technology, Beckman Institute (139-73), Pasadena, CA 91125
Quantum mechanics calculations (B3LYP and MPW1K density functional theory) on mechanisms relevant to the Wacker process for dehydrogenation of alcohol to ketone show that the commonly accepted mechanism for product formation (β-hydride elimination (BHE) leading to Pd-H formation) is not energetically feasible (36.2 kcal/mol). An alterative pathway involving a five-bodied reductive elimination (RE) leads to an activation enthalpy of 18.8 kcal/mol, which is just half that of the BHE from the -OH group usually assumed for the Wacker process. We find that a water molecule catalyzes both processes, reducing the barrier to 17.2 for RE and 25.0 for BHE, but will not change the relative ordering of the two mechanisms. This suggests that assumptions of BHE mechanisms should be reexamined for cases in which the β atom is not an alkyl group.

 

Computational Chemistry
7:00 PM-10:00 PM, Tuesday, 12 September 2006 Moscone Center -- Hall D, Poster

Division of Inorganic Chemistry

The 232nd ACS National Meeting, San Francisco, CA, September 10-14, 2006