Tautomerization in porphycenes, constitutional
isomers of porphyrins,
is strongly entangled with spectral and photophysical parameters.
The intramolecular double hydrogen transfer occurring in the ground
and electronically excited states leads to uncommon spectroscopic
characteristics, such as depolarized emission, viscosity-dependent
radiationless depopulation, and vibrational-mode-specific tunneling
splittings. This review starts with documentation of the electronic
spectra of porphycenes: Absorption and magnetic circular dichroism
are discussed, together with their analysis based on the perimeter
model. Next, photophysical characteristics are presented, setting
the stage for the final part, which discusses the developments in
research on tautomerism. Porphycenes have been studied in different
experimental regimes: molecules in condensed phases, isolated in supersonic
jets and helium nanodroplets, and, recently also on the level of single
molecules investigated by optical and scanning probe microscopies.
Because of the rich and detailed information obtained from these diverse
investigations, porphycenes emerge as very good models for studying
the complex, multidimensional phenomena involved in the process of
intramolecular double hydrogen transfer.