Rapid, green disulphide bond formation in water using the corrin dicyanocobinamide.

Peptide chemists seek rapid methods combined with facile purification when producing disulphide bonds post solid-phase synthesis. Current methods typically require long reaction times of up to two days, can result in side-products from over-oxidation and/or degradation, require organic solvents, and/or require challenging purification. Herein, we describe a rapid, green, and facile oxidation of a series of peptides with up to three disulphide bonds.

Photocatalytic turnover of CO under visible light by [Re(CO)(1-(1,10) phenanthroline-5-(4-nitro-naphthalimide))Cl] in tandem with the sacrificial donor BIH.

Optimized photocatalytic conversion of CO requires new potent catalysts that can absorb visible light. The photocatalytic reduction of CO using rhenium(i) has been demonstrated but suffers from low turnover. Herein, we describe a [Re(CO)(1-(1,10)phenanthroline-5-(4-nitro-naphthalimide))Cl] photocatalyst, which when combined with the sacrificial donor 1,3-dimethyl-2-phenyl-2,3-dihydro-1-benzo[]imidazole, results in selective production of formic acid and a high turnover number of 533 and turnover frequency of 356 h.

[Re(CO)(5-PAN)Cl], a rhenium(I) naphthalimide complex for the visible light photocatalytic reduction of CO.

A rhenium(i) naphthalimide complex [Re(CO)3(5-PAN)Cl] (Re(5-PAN); 5-PAN = 1-(1,10-phenanthroline)-4-nitro-naphthalimide) was synthesized, characterized, and evaluated as a photocatalyst for CO2 reduction. Characterization included use of MALDI-ToF mass spectrometry, FT-IR, RAMAN, 1H and 13C NMR, elemental analysis, electronic absorption and emission spectroscopy, single crystal X-ray diffraction, DFT and cyclic voltammetry. Photocatalytic (406 nm) reduction of 13CO2 to formate (H13COO) in the presence of this catalyst was tracked via13C NMR.