posted on 2023-09-29, 17:37authored bySi-Cong Liu, De-Cai Fang
Density functional theory (DFT) calculations have been
employed
to investigate the mechanism of carboamination and diamination of
unactivated alkenes mediated by Pd(IV) intermediates. Both reactions
share a common Pd(IV) intermediate, serving as the starting point
for either the carboamination or the diamination pathway. The formation
of this Pd(IV) intermediate encompasses a transition state that substantially
impacts the turnover frequency (TOF) of catalytic cycles, with an
apparent activation free-energy barrier of 26.1 kcal mol–1. Carboamination of unactivated alkenes proceeds through the coordination
of a toluene molecule, C–H activation, inner reductive elimination,
and the separation of the carboamination product from this intermediate,
while diamination of unactivated alkenes involves the formation of
the ion nucleophile, SN2 attack, and the separation of
the diamination product. A comparison of the free-energy profiles
for carboamination and diamination of unactivated alkenes can elucidate
the origin of the chemoselectivity, and Bader’s atoms in molecules
(AIM) wave function analyses have been performed to analyze the contributions
of the outer C–N bonding in the diamination process.