It has been established that an electron-deficient cationic CpE-rhodium(III) complex catalyzes the non-oxidative [2+2+2] annulation of N-(1-naphthyl)acetamide with two alkynoates via cleavage of the adjacent C⁻H and C⁻N bonds to give densely substituted phenanthrenes under mild conditions (at 40 °C under air). In this reaction, a dearomatized spiro compound was isolated, which may support the formation of a cationic spiro rhodacycle intermediate in the catalytic cycle. The use of N-(1-naphthyl)acetamide in place of acetanilide switched the reaction pathway from the oxidative [2+2+2] annulation-lactamization via C⁻H/C⁻H cleavage to the non-oxidative [2+2+2] annulation via C⁻H/C⁻N cleavage. This chemoselectivity switch may arise from stabilization of the carbocation in the above cationic spiro rhodacycle by the neighboring phenyl and acetylamino groups, resulting in the nucleophilic C⁻C bond formation followed by β-nitrogen elimination.
Keywords: C–H bond cleavage; C–N bond cleavage; N-(1-naphthyl)acetamide; [2+2+2] annulation; alkynes; cyclopentadienyl complexes; rhodium.