The first transition metal-free catalyzed direct C–H arylation of a variety of heteroarenes at room temperature has been reported using a phenalenyl-based radical without employing any photoactivation step.
Phenalenyl,
a zigzag-edged odd alternant hydrocarbon unit can be
found in the graphene nanosheet. Hückel molecular orbital calculations
indicate the presence of a nonbonding molecular orbital (NBMO), which
originates from the linear combination of atomic orbitals (LCAO) arising
from 13 carbon atoms of the phenalenyl molecule. Three redox states
(cationic, neutral radical, and anionic) of the phenalenyl-based molecules
were attributed to the presence of this NBMO. The cationic state can
undergo two consecutive reductions to result in neutral radical and
anionic states, stepwise, respectively. The phenalenyl-based radicals
were found as crucial building blocks and attracted the attention
of various research fields such as organic synthesis, material science,
computation, and device physics. From 2012 onward, a strategy was
devised using the cationic state of phenalenyl-based molecules and
in situ generated phenalenyl radicals, which created a new domain
of catalysis. The in situ generated phenalenyl radicals were utilized
for the single electron transfer (SET) process resulting in redox
catalysis. This emerging range of applications rejuvenates the more
than six decades-old phenalenyl chemistry. This review captures such
developments ranging from fundamental understanding to multidirectional
applications of phenalenyl-based radicals.
In recent years, merging different types of catalysis in a single pot has drawn considerable attention and these catalytic processes have mainly relied upon metals. However, development of a completely metal free approach integrating organic redox and organic Lewis acidic property into a single system has been missing in the current literature. This study establishes that a redox active phenalenyl cation can activate one of the substrates by single electron transfer process while the same can activate the other substrate by a donor-acceptor type interaction using its Lewis acidity. This approach has successfully achieved light and metal-free catalytic C-H functionalization of unactivated arenes at ambient temperature (39 entries, including core moiety of a top-selling molecule boscalid), an economically attractive alternative to the rare metal-based multicatalysts process. A tandem approach involving trapping of reaction intermediates, spectroscopy along with density functional theory calculations unravels the dual role of phenalenyl cation.
A doubly reduced redox non-innocent phenalenyl based transition metal free catalyst has been designed and utilized in the development of the C–C cross coupling reaction through the activation of aryl halides at room temperature.
Open-shell phenalenyl chemistry has widely been explored in the last five decades demonstrating its potential in various applications including molecular switch, spin memory device, molecular battery, cathode material, etc. In this article, we have explored another new direction of open-shell phenalenyl chemistry toward transition metal-free catalytic C-H functionalization process. A phenalenyl ligand, namely, 9-methylamino-phenalen-1-one (4a), promoted chelation-assisted single electron transfer (SET) process, which facilitates the C-H functionalization of unactivated arenes to form the biaryl products. The present methodology offers a diverse substrate scope, which can be operated without employing any dry or inert conditions and under truly transition metal based catalyst like loading yet avoiding any expensive or toxic transition metal. This not only is the first report on the application of phenalenyl chemistry in C-H functionalization process but also provides a low-catalyst loading organocatalytic system (up to 0.5 mol % catalyst loading) as compared to the existing ones (mostly 20-40 mol %), which has taken advantage of long known phenalenyl based radical stability through the presence of its low-lying nonbonding molecular orbital.
We report the first earth abundant single mononuclear Mn(iii) complex which can selectively and catalytically transform primary amides to nitriles as well as reduce primary amides to amines.
Borrowing hydrogen from alcohol, storing it on the catalyst and subsequent transfer of the hydrogen from catalyst to an in situ generated imine is the hallmark of a transition metal...
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