posted on 2024-12-03, 19:20authored byShahriar
N. Khan, John H. Hymel, John P. Pederson, Jesse G. McDaniel
In anodic electrosynthesis, cation radicals are often
key intermediates
that can be highly susceptible to nucleophilic attack and/or deprotonation,
with the selectivity of competing pathways dictating product yield.
In this work, we computationally investigate the role of methanol
in alcohol trapping of enol ether cation radicals for which substantial
modulation of the reaction yield by the solvent environment was previously
observed. Reaction free energies computed for intramolecular coupling
unequivocally demonstrate that the key intramolecular alcohol attack
on the oxidized enol ether group is catalyzed by methanol, proceeding
through overall second-order kinetics. Methanol complexation with
the formed oxonium ion group gives rise to a “Zundel-like”,
shared proton conformation, providing a critical driving force for
the intramolecular alcohol attack. Free energies computed for methanol
solvent attack of enol ether cation radicals demonstrate an analogous
mechanism and overall third-order kinetics, due to similar complexation
from a secondary methanol molecule to form the “Zundel-like”,
shared proton conformation. As catalyzed by methanol, both intramolecular
alcohol attack and methanol attack on the oxidized enol ether group
are barrierless or low-barrier reactions, with kinetic competition
dictated by the conformational free energy profile of the cation radical
substrate and the difference in reaction rate orders.