Regiochemical Aspects of the Platinum Oxide Catalyzed Hydrosilylation of Alkynes

 

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Abstract

The platinum-catalyzed hydrosilylation of unsymmetrical substituted arylalkynes with various hydrosilanes was investigated and the reaction selectivity of various para-substituted substrates was compared with that of their corresponding ortho-substituted derivatives. We showed that heterogeneous platinum oxide is a very efficient catalyst for such hydrosilylations and that H-Si bond addition proceeds in a stereoselective cis-fashion. The regioselectivity was found to be under the control of the ortho-substituent rather than due to the nature of the platinum catalyst. Aryl­alkynes with an ortho-substituent provided predominantly to exclusively α-selectivity, regardless of the electronic nature of the substituent. The precise contributions of steric, electronic, and coordinative factors controlling the regioselectivity of the H-Si bond addition are discussed.

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Treatment of 2b with Et₃SiH (1.5 equiv) in the presence of H₂PtCl₆ or Pt/C (5 mol%) at 60 °C for a prolonged time (3 h) did not promote any protodesilylation of 2b, indicating that the reduced side product was formed from starting material 1b.

Performing the hydrosilylation of 10a at 60 °C led to a mixture of α- (10%) and β-isomers (23%) together with the protodesilylated product (67%).