Generation and Oxidative Reactivity of a Ni(II) Superoxo Complex via Ligand-Based Redox Non-Innocence

Abstract: Metal ligand cooperativity is a powerful strategy in transition metal chemistry. This type of mechanism for the activation of O₂ is best exemplified by heme centers in biological systems. While aerobic oxidations with Fe and Cu are well precedented, Ni-based oxidations are frequently less common due to less-accessible metal-based redox couples. Some Ni enzymes utilize special ligand environments for tuning the Ni(II)/(III) redox couple such as strongly donating thiolates in Ni superoxide… Show more

“…Complex 1 was synthesized following a previously reported procedure. 59 All manipulations were carried out under an atmosphere of N 2 by using standard Schlenk and glovebox techniques. Glassware was dried at 180 °C for a minimum of 2 h and cooled under vacuum prior to use.…”

“…The EPR spectrum is distinct from that of complex 1 which is formally Ni(II) with a ligand radical. 59 These combined data, and particularly the need to add an additional reductant to 3 to react with alkynes, supports that a reduction to a Ni(I) species ( 4) is critical to initiating catalysis. With evidence supporting the necessity of the two-electron reduction of 1 in the presence of acid before the system is catalytically active, we then investigated the chronoamperometry of bulk electrolyses to gain additional mechanistic insights.…”

“…We initially targeted the previously reported complex ( tBu,Tol DHP)Ni(II) (1) as a precatalyst. 59 The cyclic voltammogram (CV) of 1 in acetonitrile shows two reversible redox events at peak potentials (E 1/2 ) of −0.1 and −1.1 V vs Fc 0/+ . We assign these features to ligand-based oxidation and reduction of the starting complex to form 1 + and 1 − , respectively (Figure 2A).…”

Electrocatalytic Semihydrogenation of Terminal Alkynes Using Ligand-Based Transfer of Protons and Electrons

“…Complex 1 was synthesized following a previously reported procedure. 59 All manipulations were carried out under an atmosphere of N 2 by using standard Schlenk and glovebox techniques. Glassware was dried at 180 °C for a minimum of 2 h and cooled under vacuum prior to use.…”

“…The EPR spectrum is distinct from that of complex 1 which is formally Ni(II) with a ligand radical. 59 These combined data, and particularly the need to add an additional reductant to 3 to react with alkynes, supports that a reduction to a Ni(I) species ( 4) is critical to initiating catalysis. With evidence supporting the necessity of the two-electron reduction of 1 in the presence of acid before the system is catalytically active, we then investigated the chronoamperometry of bulk electrolyses to gain additional mechanistic insights.…”

“…We initially targeted the previously reported complex ( tBu,Tol DHP)Ni(II) (1) as a precatalyst. 59 The cyclic voltammogram (CV) of 1 in acetonitrile shows two reversible redox events at peak potentials (E 1/2 ) of −0.1 and −1.1 V vs Fc 0/+ . We assign these features to ligand-based oxidation and reduction of the starting complex to form 1 + and 1 − , respectively (Figure 2A).…”

Electrocatalytic Semihydrogenation of Terminal Alkynes Using Ligand-Based Transfer of Protons and Electrons

“…The CW X-band EPR spectra of O 2 reactions with both 1 and 2 display signals with slight rhombic distortion (1: g av = 2.24, 2: g av = 2.23), where the lowfield signal value is shifted to lower magnetic field compared to reported Ni−O 2 adducts. 29,31,32,47,91 The CW X-band EPR spectrum of the reaction between 10 and O 2 at 130 K displays a signal (g av = 2.20), with resolved hyperfine coupling. 92 Spin quantification data using a TEMPO standard established that the EPR signals above accounted for at most 37% of the nickel.…”

Appended Lewis Acids Enable Dioxygen Reactivity and Catalytic Oxidations with Ni(II)

“…1−6 Extensive efforts have been made to design and develop new efficient catalysts for ORR and to understand catalyst structural effects on their activities. 7−11 On one hand, these efforts lead to the identification of a large number of metal complexes, including those of Mn, 12−15 Fe, 16−19 Co, 20−24 Ni, 25,26 and Cu, 27−29 as active catalysts for ORR. More importantly, fundamental knowledge to correlate the structure and the catalytic performance of ORR catalysts is learned.…”

Steric Effects on the Oxygen Reduction Reaction with Cobalt Porphyrin Atropisomers