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cyclodehydrogenation

Cyclodehydrogenation is a chemical reaction in which adjacent aryl units are fused by removing hydrogen, forming new carbon–carbon bonds and enlarging the fused-ring system. The process converts linear or sparsely connected arene precursors into polycyclic aromatic hydrocarbons (PAHs) with extended conjugation. It is a key step in the dehydrogenative synthesis of nanographenes and other PAHs from preorganized polyaryl substrates.

Most widely used forms are oxidative cyclodehydrogenations, often called Scholl-type reactions, which promote intramolecular ring closure

Applications of cyclodehydrogenation include the synthesis of classic PAHs such as pyrene, phenacenes, and larger nanographenes

See also Scholl reaction and oxidative cyclodehydrogenation.

between
adjacent
aryl
rings.
These
reactions
typically
employ
strong
Lewis
acids
such
as
aluminum
trichloride
or
ferric
chloride,
sometimes
in
combination
with
oxidants,
and
are
carried
out
at
elevated
temperatures.
Alternative
oxidative
methods
use
reagents
such
as
DDQ
(2,3-dichloro-5,6-dicyano-p-benzoquinone)
or
cerium(IV)
salts.
In
addition,
catalytic
dehydrogenative
cyclizations
using
transition
metals
(for
example,
palladium
or
copper
catalysts
under
oxidizing
conditions)
have
been
reported.
The
exact
mechanism
can
involve
generation
of
aryl
cations
or
radicals,
followed
by
cyclization
and
rearomatization.
like
hexabenzocoronene,
often
from
preorganized
hexaaromatic
or
hexaarylbenzene
precursors.
The
method
enables
rapid
construction
of
planar,
highly
conjugated
rings
but
can
suffer
from
regioselectivity
challenges,
side
reactions,
and
limited
yields
for
large
systems.
Substituents
and
substrate
design
are
important
to
control
fusion
patterns
and
prevent
over-oxidation.