posted on 2022-11-29, 08:03authored byRemy F. Lalisse, Christopher M. Hadad, Christian Brückner, Matthew J. Guberman-Pfeffer
Removal of a β,β′-bond from meso-tetraarylporphyrin using [3 + 2]-cycloadditions generates meso-tetraarylhydroporphyrins. Literature evidence indicates
that meso-tetraphenylporphyrins react more sluggishly
with 1,3-dipoles such as ylides and OsO4 (in the presence
of pyridine) than meso-tetrakis(pentafluorophenyl)porphyrin.
The trend is counterintuitive for the reaction with OsO4, as this formal oxidation reaction is expected to proceed more readily
with more electron-rich substrates. This work presents a density functional
theory–based computational study of the frontier molecular
orbital (FMO) interactions and reaction profile thermodynamics involved
in the reaction of archetypical cycloaddition reactions (a simple
ylide, OsO4, OsO4·py, OsO4·(py)2, and ozone) with the β,β′-double bonds
of variously fluorinated meso-arylporphyrins. The
trend observed for the Type I cycloaddition of an ylide is straightforward,
as lowering the LUMO of the porphyrin with increasing meso-phenyl-fluorination also lowers the reaction barrier. The corresponding
simple FMO analyses of Type III cycloadditions do not correctly model
the reaction energetics. This is because increasing fluorination leads
to lowering of the porphyrin HOMO–2, thus increasing the reaction
barrier. However, coordination of pyridine to OsO4 preorganizes
the transition state complex; lowering of the energy barrier by the
preorganization exceeds the increase in repulsive orbital interactions,
overall accelerating the cycloaddition and rationalizing the counterintuitive
experimental findings.