73. Mechanistic insight into Cp*Rh(III)-catalyzed Lossen rearrangement vs C–N reductive elimination for the synthesis of pyridones

Ling, B.;* Xu, J.; Jiang, Y.-Y.; Liu, P.; Feng, J.; Bi, S.*  New J. Chem. 2022, 46, 16485–16494. Download Link.

Abstract: A comprehensive density functional theory study has been performed on the mechanism of Cp*Rh(III)- catalyzed C–H activation of N-(pivaloyloxy)acrylamide with alkynyl triazene. The calculated results reveal that a concerted Lossen rearrangement/OPiv migration from N to Rh is the most favorable pathway to afford an isocyanate intermediate, where a redox-neutral process is involved without the involvement of a Rh(V)-nitrenoid species. Subsequently, the annulation of a rearranged six-membered ring intermediate is realized through a nucleophilic attack of Rh-bonded carbon on the isocyanate carbon, and this process is likely to be the rate-determining step for the entire catalytic cycle, with an overall energy barrier of 20.5 kcal mol1. In addition, the stepwise OPiv migration from N to Rh and C–N reductive elimination, and vice versa, are competitive to yield a non-rearranged byproduct, which experiences a Rh(III)–Rh(V)–Rh(III) transformation of oxidation state.