Fixation of atmospheric CO as C1-feedstock by nickel(ii) complexes.

The development of molecular catalysts for the activation and conversion of atmospheric carbon dioxide (CO) into a value-added product is a great challenge. A series of nickel(ii) complexes, Ni(L)(CHCN), 1-4 of diazepane based ligands, 4-methyl-1-[(pyridin-2-yl-methyl)]-1,4-diazepane (L1), 4-methyl-1-[2-(pyridine-2-yl)ethyl]-1,4-diazepane (L2), 4-methyl-1-[(quinoline-2-yl)-methyl]-1,4-diazepane (L3) and 1-[(4-methoxy-3,5-dimethyl-pyridin-2-yl)methyl]-4-methyl-1,4-diazepane (L4), have been synthesized and characterized as catalysts for the activation of atmospheric CO. The single-crystal X-ray structure of 1 shows a distorted octahedral geometry with a cis-β configuration around the NiN coordination sphere. All the complexes are used as catalysts for the conversion of atmospheric CO and epoxides into cyclic carbonates at 1 atmosphere (atm) pressure and in the presence of EtN. Catalyst 4 was found to be the most efficient catalyst and showed a 31% formation of cyclic carbonates with a TON of 620 under 1 atm air as the CO source. This yield was enhanced to 94% with a TON of 1880 under 1 atm pure CO gas and it is the highest catalytic efficiency known for nickel(ii)-based catalysts. Catalyst 4 enabled the transformation of a wide range of epoxides (eight examples) into corresponding cyclic carbonates with excellent selectivity (>99%) and yields of 59-94% and 11-31% under pure CO and atmospheric CO, respectively. The catalytic efficiency is strongly influenced by the electronic nature of the complexes. The CO fixation reactions without an epoxide substrate led to the formation of the carbonate bridged dinuclear nickel(ii) complexes (LNi)CO1a-4a, which are speculated as catalytically active intermediates. The formation of these species was accompanied by the formation of new absorption bands around 592-681 nm and was further confirmed by the ESI-MS and IR spectral studies. The molecular structures of these carbonate-bridged key intermediates were determined by X-ray analysis. The structures contain two Ni-centers bridged via a carbonate ion that originated from CO. Distorted square pyramidal geometries are adopted around each Ni(ii) center. All these results support that CO fixation reactions occur via CO-bound nickel key intermediates.