This work presents three mononuclear Ru(II) complexes of tridentate phosphine-carboxamide based ligands providing NNP coordination environment. The octahedral Ru(II) ion receives additional coordinations from co-ligands; CO, Cl and CH3OH. All...
We
present synthesis and characterization of two half-sandwich
Ru(II) complexes supported with amide-phosphine based ligands. These
complexes presented a pyridine-2,6-dicarboxamide based pincer cavity,
decorated with hydrogen bonds, that participated in the binding of
nitro-substrates closer to the Ru(II) centers, which is further supported
with binding and docking studies. These ruthenium complexes functioned
as the noteworthy catalysts for the borohydride mediated reduction
of assorted nitro-substrates. Mechanistic studies not only confirmed
the intermediacy of [Ru–H] in the reduction but also asserted
the involvement of several organic intermediates during the course
of the catalysis. A similar Ru(II) complex that lacked pyridine-2,6-dicarboxamide
based pincer cavity substantiated its unique role both in the substrate
binding and the subsequent catalysis.
Cobalt complexes of amide‐based ligands appended with protonated heterocyclic rings are utilized as the earth‐abundant catalysts for the transfer hydrogenation of assorted carbonyl compounds using isopropanol as the hydrogen source. The most successful complex illustrated remarkable catalytic performance towards a wide range of aldehydes and ketones, quantitatively yielding primary and secondary alcohols as the products, respectively. The catalysis scope also included a few biologically relevant substrates such as furfural, vanillin, ortho‐vanillin, coumarin and chalcone. The substrate binding, Hammett, kinetic and DFT studies provided the mechanistic insights.
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