by David D. Ford, Lars P. C. Nielsen, Stephan J.
Zuend, Charles B. Musgrave and Eric N. Jacobsen*
In the (salen)Co(III)-catalyzed hydrolytic kinetic
resolution (HKR) of terminal epoxides, the rate- and
stereoselectivity-determining epoxide ring-opening step occurs by a cooperative
bimetallic mechanism with one Co(III) complex acting as a Lewis acid and
another serving to deliver the hydroxide nucleophile. In this paper, we analyze
the basis for the extraordinarily high stereoselectivity and broad substrate
scope observed in the HKR. We demonstrate that the stereochemistry of each of
the two (salen)Co(III) complexes in the rate-determining transition structure
is important for productive catalysis: a measurable rate of hydrolysis occurs
only if the absolute stereochemistry of each of these (salen)Co(III) complexes
is the same. Experimental and computational studies provide strong evidence
that stereochemical communication in the HKR is mediated by the stepped
conformation of the salen ligand, and not the shape of the chiral diamine
backbone of the ligand. A detailed computational analysis reveals that the epoxide
binds the Lewis acidic Co(III) complex in a well-defined geometry imposed by
stereoelectronic rather than steric effects. This insight serves as the basis
of a complete stereochemical and transition structure model that sheds light on
the reasons for the broad substrate generality of the HKR.
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