Transition metal catalysed direct
arylation of aromatic C-H bonds is emerging as a valuable and efficient
alternative to traditional cross-coupling in the construction of biaryl
compounds. Selective functionalization of aromatic C–H bonds is now an important
aspect of this rather general field due to the universal existence of aromatic
functionalities in nature and the synthetic world. ‘Fenton’ chemistry and Friedel–Crafts reactions
are early examples of transformations of aryl C–H bonds to different
functionalities.
Many reports have demonstrated that
direct arylation of heterocycles, arenes with directing groups, and
electron-deficient arenes(1-7). As well a completely unactivated arene, benzene
has been directly arylated by a few efficient transition-metal-catalyzed methods
(8-12).
In 2003, Leadbeater et.al,. reported
a transition metal free Suzuki coupling reaction in water using sodium
carbonate as a base(13-14)(Scheme-1). Later, the same group reported the
transition metal free sonogashira type reaction (15)(Scheme-2). After that they
discovered that the reaction was in fact metal-mediated — by palladium
contaminants of as little as 50 ppb that were present in the sodium carbonate base
used. In 2009, Buchwald reported that iron catalysed cross coupling reaction
has been done by copper catalyst which is an impurity in Iron source(16).
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| Scheme-1 |
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| Scheme-2 |
In 2008, Daugulis, reported transition-metal-free,
base-mediated intramolecular arylation of phenols with aryl halides. The sp2 C-H
bond functionalization occurs via a benzyne intermediate. At this point, a phenolate
activating group is essential for the arylation(17)(Scheme-3). In the same
time, Itami et al. reported a transition metal free direct C-H arylation electron
deficient nitrogen heterocycles using haloarenes. As well, they also reported a
transition-metal-free systems for the cross coupling reactions of nitrogen
heteroaromatics and alkanes (18-19)(Scheme-4). Itami et al. proposed a radical
pathway for the sole KOBut promoted direct arylation of
electron-deficient nitrogen heterocycles with aryl iodides.
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| Scheme-3 |
 |
| Scheme-4 |
Recently, the most notable examples are three ‘transition
matal free’ methods for pereparing biaryls by C-H activation.
Now, these reports getting a lot
of attention, and a lot of raised eyebrows. The authors claim that they can
couple aryl iodides with unfunctionalized aromatic compounds with
nitrogen bidentate ligands as catalysts - and no transition metals at
all - just potassium or sodium t-butoxide as base. Organic chemists
will recognize that this is a very unusual reaction indeed, since carbon-carbon
bonds between aryl groups are not supposed to be so easy to form. This
reaction, in fact, would suggest that a lot of the palladium-catalyzed work is
some sort of odd detour to get to a process that happens fairly easily anyway.
The authors suggest that since
they're using iodides that a free radical mechanism is operating. Addition of
radical scavengers, they say, shuts the reaction down. The fact that they don't
get regioisomers, that rules out another possible mechanism through benzyne
intermediates.
 |
| Scheme-5 |
The authors Liu, W.; as well Sun,
C.L.; mentioned that, In order to eliminate the possibility of the presence of
trace transition metal elements in the commercially available potassium tert-butoxide
that would potentially affect our investigation, they purified the KOBut by
sublimation prior to their examination. Almost the same results were obtained
between the nonpurified and purified base.
Could trace amounts of transition
metal have contaminated the experiment? 'Obviously this is one of the most
important factors,' says Lei. 'We have checked the contamination of trace
amounts of transition metals by ICP [inductively coupled plasma atomic emission
spectroscopy] and excluded the involvement of small amounts of transition
metals in this transformation.'
Commenting on the work, Carsten
Bolm, an organic synthesis expert
from Aachen University in Germany, says, 'To be able to
prepare cross-coupling products without the use of transition metals is an
important scientific advance. Although at the present stage the substrate
scope is by far too limited to make the process synthetically attractive, the
findings illustrate that new reaction paths in direct C-H arylations are still
to be discovered, and as such this work will be highly stimulating to the
community.'
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