This review surveys
recent progress in the chemistry of polycyclic
heteroaromatic molecules with a focus on structural diversity and
synthetic methodology. The article covers literature published during
the period of 2016–2020, providing an update to our first review
of this topic (
Chem. Rev.
2017
,
117
(4), 3479–3716).
A 139-π-electron
nanographenoid radical was obtained by expanding
the periphery of a naphthalimide–azacoronene hybrid with a
methine bridge. The radical was isolated in the form of its σ-dimer,
which was shown to possess a conformationally restricted two-layer
structure both in the solid state and in solution. The dimer is cleaved
into its parent radicals when exposed to ultraviolet or visible radiation
in toluene solutions but is resistant to thermally induced dissociation.
Under inert conditions, the radicals recombine quantitatively into
the σ-dimer with observable kinetics, but they are oxidized
into a ketone derivative in the presence of atmospheric oxygen. Combined
structural, spectroscopic, and theoretical evidence shows that the
σ-dimer contains a weak C(sp
3
)–C(sp
3
) bond, but is stabilized against thermal dissociation by a very
strong dispersive interaction between the overlapping π surfaces.
Pd -mediated annulative double C-H activation is shown to efficiently convert 1,n-dipyrrolylalkanes into extensively π-conjugated bipyrroles not accessible by conventional oxidative coupling protocols. This approach is applicable to both electron-rich and electron-deficient systems, and has been further developed into tandem processes involving further cyclization of substituents or oxygenation of pyrrolic α-positions. The new bipyrrole intermediates show enhanced fluorescence as well as tunable optical properties controlled by the alignment of chromophore subunits. Photophysical data, including femtosecond transient absorptions, reveal solvent-induced intramolecular charge transfer in their excited states, dependent on the polarity of the medium.
1, n-Dipyrrolylalkanes can be efficiently converted into extensively π-conjugated bipyrroles by Pd-mediated annulative double C-H activation, and this approach might be further developed into tandem processes involving further cyclization of substituents or oxygenation of pyrrolic α-positions. Herein, the mechanism of these transformations is explored using NMR spectroscopy and DFT calculations. The kinetics of the annulation are found to depend on the conjugation extent and donor-acceptor character of the pyrroles, as well as on substitution and the linker length. Combined experimental and theoretical evidence indicates that a change of the rate-determining step occurs for the most electron-deficient substrates. The unprecedented double α-oxygenation of bipyrroles is found to be a stepwise process, involving α-acetoxylated intermediates.
Boomerang-shaped bipyrroles containing donor–acceptor units were obtained through a tandem palladium-mediated reaction consisting of a cyclization step, involving double C–H bond activation, and a double α-oxygenation. The latter reaction can be partly suppressed for the least reactive systems, providing access to α-unsubstituted boomerangs for the first time. These “α-free” systems are highly efficient fluorophores, with emission quantum yields exceeding 80% in toluene. Preliminary measurements show that helicene-like boomerangs may be usable as circularly polarized luminescent materials.
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