Well-defined cobalt(II)-catalyzed synthesis of perimidine derivatives acceptorless dehydrogenative annulation.

The versatility of the perimidine moiety offers a rich playground for researchers in fields ranging from medical science to industrial chemistry. Herein, we describe the first Co-catalyzed synthesis of 2,3-dihydro-1-perimidine acceptorless dehydrogenative annulation (ADA). Apart from featuring benzyl alcohol having different functionalities, heteroaryl and aliphatic alcohols also provide good yields.

Redox-enabled cooperative catalysis by activating secondary alcohols using low-valent Zn complexes.

Inspired by nature's redox management in bioinorganic systems, we developed various Zn-complexes to catalyze a radical-mediated borrowing hydrogen process for producing β-disubstituted ketones. A diverse range of secondary alcohols, including fatty alcohols, terpenoids and steroid analogs, were successfully utilized for the chemoselective functionalization of ketones. Several organometallic and control studies suggest that coordinatively unsaturated radical species operate as active catalysts to promote alcohol activation and initiate the HAT process.

Experimental and theoretical insights for designing Zn complexes to trigger chemo-selective hetero-coupling of alcohols.

Designing well-defined Zn-complexes for sustainable dehydrogenative catalysis overcoming the difficulties associated with activating Zn(d)-metal species is considered paramount goal in catalysis. Herein, we explore the plausibility of β-alkylation of secondary alcohols with primary alcohols by well-defined 3d Zn-complexes. Detailed organometallic and catalytic investigations, in conjunction with computational analyses, were conducted to ascertain the potential involvement of the catalyst at various stages of the catalytic process.

Designing Cobalt(II) Complexes for Tandem Dehydrogenative Synthesis of Quinoline and Quinazoline Derivatives.

In this work, we have constructed three new Co(II) complexes in which steric features govern their structural geometry. The metal ligand-cooperation behavior of the alkoxy arm is utilized to explore the catalytic activities of these complexes with respect to dehydrogenation. A wide range of C-3-substituted quinoline and quinazoline derivatives were synthesized in high yields.

Manganese Complex Catalyzed Sequential Multi-component Reaction: Enroute to a Quinoline-Derived Azafluorenes.

The development of innovative synthetic strategies for constructing complex molecular structures is the heart of organic chemistry. This significance of novel reactions or reaction sequences would further enhance if they permitted the synthesis of new classes of structural motifs, which have not been previously created. The research on the synthesis of heterocyclic compounds is one of the most active topics in organic chemistry due to the widespread application of N-heterocycles in life and material science.

Well-Defined Mn(II)-complex Catalyzed Switchable De(hydrogenative) Csp -H Functionalization of Methyl Heteroarenes: A Sustainable Approach for Diversification of Heterocyclic Motifs.

Catalytic activities of Mn(I) complexes derived from expensive MnBr(CO) salt have been explored in various dehydrogenative transformations. However, the reactivity and selectivity of inexpensive high spin Mn(II) complexes are uncommon. Herein, we have synthesized four new Mn(II) complexes and explored switchable alkenylation and alkylation of methyl heteroarenes employing a single Mn(II)catalyst.

Ruthenium-catalyzed dehydrogenative cyclization to synthesize polysubstituted 4-quinolones under solvent-free conditions.

Herein, we describe acridine-based SNS-Ru pincer-catalysed unprecedented dehydrogenative annulation of alcohols with 2'-aminoacetophenone to synthesize 2,3-disubstituted-4-quinolones. The developed protocol was utilized with a wide range of alcohols with various aminoacetophenones. To expand the synthetic utility, 4-quinolones with antibiotic properties were synthesized and various important post-synthetic modifications of the synthesized scaffolds were performed.

Well-Defined NNS-Mn Complex Catalyzed Selective Synthesis of C-3 Alkylated Indoles and Bisindolylmethanes Using Alcohols.

Herein, we demonstrated Mn-catalyzed selective C-3 functionalization of indoles with alcohols. The developed catalyst can also furnish bis(indolyl)methanes from the same set of substrates under slightly modified reaction conditions. Mechanistic studies reveal that the C-3 functionalization of indoles is going via a borrowing hydrogen pathway.

Manganese catalyzed switchable -alkylation/alkenylation of fluorenes and indene with alcohols.

The usage of earth-abundant, nontoxic transition metals in place of rare noble metals is a central goal in catalysis. This would be especially interesting when the reactivity and selectivity patterns can be tuned. Herein, we introduced the first Mn-catalyzed selective -alkylation and olefination of fluorene, and indene with alcohols.

Sustainable Synthesis of Quinazoline and 2-Aminoquinoline via Dehydrogenative Coupling of 2-Aminobenzyl Alcohol and Nitrile Catalyzed by Phosphine-Free Manganese Pincer Complex.

A sustainable synthesis of quinazoline and 2-aminoquinoline via acceptorless dehydrogenative annulation is presented. The reaction is catalyzed by earth-abundant well-defined manganese complexes bearing NNS ligands. Furthermore, a one-pot synthetic strategy for the synthesis of 2-alkylaminoquinolines through sequential dehydrogenative annulation and N-alkylation reaction has also been demonstrated.