Abstract
Oxidative
C–H/C–H coupling is a promising synthetic route for the streamlined
construction of conjugated organic materials for optoelectronic applications. Broader
adoption of these methods is nevertheless hindered by the need for catalysts that
excel in forging core semiconductor motifs, such as ubiquitous oligothiophenes,
with high efficiency in the absence of metal reagents. We report a
(thioether)Pd-catalyzed oxidative coupling method for the rapid assembly of both
privileged oligothiophenes and challenging hindered cases, even at low catalyst
loading under Ag- and Cu-free conditions. A combined experimental and
computational mechanistic study was undertaken to understand how a simple
thioether ligand, MeS(CH2)3SO3Na, leads to
such potent reactivity toward electron-rich substrates. The consensus from
these data is that a concerted, base-assisted C–H cleavage transition state is
operative, but thioether coordination to Pd is associated with decreased
synchronicity (bond formation exceeding bond breaking) versus the classic
concerted metalation-deprotonation (CMD) model. Enhanced positive charge
build-up on the substrate results from this perturbation, which rationalizes experimental
trends strongly favoring π-basic sites. The term electrophilic CMD (eCMD)
is introduced to distinguish this mechanism. More O'Ferrall-Jencks analysis
further suggests eCMD should be a
general mechanism manifested by many metal complexes. A preliminary
classification of complexes into those favoring eCMD or standard CMD is proposed, which should be informative for
studies toward tunable catalyst-controlled reactivity.
Supplementary materials
Title
eCMD SUPPORTING INFORMATION
Description
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