Synthesis, properties, and electrochemical studies of a series of nickel(II) complexes with related macrocyclic ligands of varied unsaturation

Abstract: Aüfc.and ß for the various donors (1.4 kcal mol-1) could be ascertained.An immediate application of the procedure outlined above is to predict the enthalpy of adduct formation of bis(hexafluoroacetylacetonato)copper(II) with trimethylamine A-oxide in carbon tetrachloride. According to Table II, the reported value in o-dichlorobenzene should be corrected by A7i[Cu(hfac)producing a value of -12.8 kcal mol-1. It is of interest to consider what approach could be taken for a system in which no adduct could be found… Show more

“…In addition to these transitions, another band is observed at 303 nm, which can be attributed to a charge-transfer transition involving orbitals from Ni II and the pyridine ligand, as previously observed for complex 1 14 and other Ni II complexes. [38][39][40] The redox properties of complexes 1 and 2 were investigated by cyclic voltammetry which revealed the presence of two irreversible anodic waves ( Figure S2) in CH 2 Cl 2 at 100 mV/s, with Fc + /Fc as the internal standard. The peaks at E ox1 ) 1.04, E ox2 ) 1.20 for complex 1 and E ox1 ) 0.73, E ox2 ) 0.94 V for complex 2 (vs NHE) are assigned to the irreversible stepwise one-electron oxidation couples Ni II Ni II / Ni II Ni III and Ni II Ni III /Ni III Ni III , respectively.…”

Synthesis, Structure, and Physicochemical Properties of Dinuclear Ni^II Complexes as Highly Efficient Functional Models of Phosphohydrolases

“…In addition to these transitions, another band is observed at 303 nm, which can be attributed to a charge-transfer transition involving orbitals from Ni II and the pyridine ligand, as previously observed for complex 1 14 and other Ni II complexes. [38][39][40] The redox properties of complexes 1 and 2 were investigated by cyclic voltammetry which revealed the presence of two irreversible anodic waves ( Figure S2) in CH 2 Cl 2 at 100 mV/s, with Fc + /Fc as the internal standard. The peaks at E ox1 ) 1.04, E ox2 ) 1.20 for complex 1 and E ox1 ) 0.73, E ox2 ) 0.94 V for complex 2 (vs NHE) are assigned to the irreversible stepwise one-electron oxidation couples Ni II Ni II / Ni II Ni III and Ni II Ni III /Ni III Ni III , respectively.…”

Synthesis, Structure, and Physicochemical Properties of Dinuclear Ni^II Complexes as Highly Efficient Functional Models of Phosphohydrolases

“…Both complexes mainly oxidize guanines present in the bulge of 1 in the presence of KHSO 5 , and NiCR-2H more readily oxidizes guanines than NiCR. The oxidation potentials of NiCR and NiCR-2H should not be responsible for their difference in guanine oxidation because both complexes have similar oxidation potential values (1.03 V versus Ag/Ag + for NiCR and 1.05 V versus Ag/Ag + for NiCR-2H, in CH 3 CN) as previously determined in [20]. In fact, the better guanine oxidation by NiCR-2H might be attributable to its stronger coordination with guanines as described in 1 H NMR.…”

Investigation on the Interactions of NiCR and NiCR-2H with DNA

“…Furthermore, epoxidation does not occur in the presence of the one-electron acceptor 2,6-di-tert-butyl-4-methylphenol. Aside from requiring somewhat higher concentrations, the catalytic properties of 5 are similar to those of nickel(II) compounds supported by tetradentate sulfonamide, [26] and di-N,NЈ-substituted oxamide ligands, [27] and differ from the cyclam-and salen-based systems, which are not catalytically active under Mukaiyama's conditions. Compound 5, in the presence of aldehyde and dioxygen, probably generates an acylperoxy radical, as proposed by Valentine and co-workers, [30] which has been shown to be a competent oxidant for olefin epoxidation.…”

“…[16,25,26] The deprotonated urea ligand of 5, therefore, does not favor the formation of a high valent Ni III species. The CV of complex 6 shows an irreversible reduction wave (data not shown).…”

Bis(formamidine–urea) Complexes of Ni^II and Cu^II:Synthesis, Characterization, and Reactivity