posted on 2022-04-29, 22:43authored byPavel
V. Zasimov, Daniil A. Tyurin, Sergey V. Ryazantsev, Vladimir I. Feldman
The family of isomeric H2C3O+• radical cations is of great interest
for physical organic chemistry
and chemistry occurring in extraterrestrial media. In this work, we
have experimentally examined a unique synthetic route to the generation
of H2C3O+• from the C2H2···CO intermolecular complex and
also considered the relative stability and monomolecular transformations
of the H2C3O+• isomers through
high-level ab initio calculations. The structures,
energetics, harmonic frequencies, hyperfine coupling constants, and
isomerization pathways for several of the most important H2C3O+• isomers were calculated at the
UCCSD(T) level of theory. The complementary FTIR and EPR studies in
argon matrices at 5 K have demonstrated that the ionized C2H2···CO complex transforms into the E-HCCHCO+• isomer, and this latter species
is supposed to be the key intermediate in further chemical transformations,
providing a remarkable piece of evidence for kinetic control in low-temperature
chemistry. Photolysis of this species at λ = 410–465
nm results in its transformation to the thermodynamically most stable
H2CCCO+• isomer. Possible implications
of the results and potentiality of the proposed synthetic strategy
to the preparation of highly reactive organic radical cations are
discussed.