Highly correlated ab initio molecular orbital calculations have
been used to study the energetics and
mechanism governing the reaction between the radical
1CH2 and H2O in gas phase and
in solution. It was found
that methylene reacts in a barrierless fashion to produce the
ylide-like intermediate methyleneoxonium,
H2C--OH2,
which in turn undergoes a 1,2-hydrogen shift to produce
CH3OH. Results obtained at the
QCISD(T)/6-311++G**//QCISD/6-311++G** level indicate that in the gas phase, the ylide
and the transition state are located 6.4 and 4.9
kcal/mol below reactants, respectively, with an intrinsic barrier for
the 1,2-hydrogen shift of 1.4 kcal/mol. In the
presence of the solvent, the ylide remains more stable than reactants
by 5.5 kcal/mol, while the energy of the transition
state is now 1.96 kcal/mol higher than reactants giving a barrier of
7.49 kcal/mol for the 1,2-hydrogen shift.
Highly correlated ab initio molecular orbital methodologies have
been used in the study of substituent effects
on the singlet−triplet gaps of a series of nitrenium ions and their
corresponding isoelectronic carbenes.
Calculations in solution were carried out with the isodensity
polarizable continuum models, IPCM. The
results show a net stabilization of the singlet species as a result of
electronic density donation of the substituents
to a vacant p orbital located in the central atom. It is shown
that this “π-donor−π-acceptor” dependence of
the singlet−triplet gap is more significant in the case of the
nitrenium ions, due to the presence of a positive
charge. In addition, it was found that the singlet−triplet gaps
decrease with the polarity of the solvent, most
likely due to stabilizing electrostatic interactions between the
solvent and the charge distribution of the singlet.
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