Kinetics of the reduction of Mn2+ at the dropping mercury electrode in non-aqueous media

“…Finally, further extending these calculations to additional species, the computed reduction of Ni I (IB)­X to Ni 0 (IB)­X or Ni 0 (IB) is calculated to occur at exceedingly negative formal potentials (∼−3 to −4 V). These calculated potentials for Ni 0 formation are significantly more negative than the reduction potentials of typical reductants used in cross-coupling reactions (e.g., ∼−1.11 V vs Fc +/0 in DMA for tetrakis­(dimethylamino)­ethylene (TDAE) or ∼−1.94 V vs Fc +/0 in DMF for Mn 0 ). , Similarly, the disproportionation of Ni I (IB)­X to Ni II (IB)­X 2 and Ni 0 (IB) is thermodynamically highly unfavorable, with a Δ G (CPCM) of ∼+57 kcal mol –1 for both X = Cl and Br. Thus, Ni 0 is unlikely to be a catalytically relevant redox state.…”

“…Reactions involving electron transfers were corrected by adding the energy of Mn 0/2+ redox couple or TDAE 0/+ , which were used as the external reducing agents in refs and . Note that we have adopted values of E ° = −1.94 V vs Fc +/0 for Mn 2+/0 obtained from the experiments in refs and and E ° = −1.34 V vs Fc +/0 for TDAE +/0 from computations in this article.…”

Electronic Structures of Nickel(II)-Bis(indanyloxazoline)-dihalide Catalysts: Understanding Ligand Field Contributions That Promote C(sp²)–C(sp³) Cross-Coupling

“…Finally, further extending these calculations to additional species, the computed reduction of Ni I (IB)­X to Ni 0 (IB)­X or Ni 0 (IB) is calculated to occur at exceedingly negative formal potentials (∼−3 to −4 V). These calculated potentials for Ni 0 formation are significantly more negative than the reduction potentials of typical reductants used in cross-coupling reactions (e.g., ∼−1.11 V vs Fc +/0 in DMA for tetrakis­(dimethylamino)­ethylene (TDAE) or ∼−1.94 V vs Fc +/0 in DMF for Mn 0 ). , Similarly, the disproportionation of Ni I (IB)­X to Ni II (IB)­X 2 and Ni 0 (IB) is thermodynamically highly unfavorable, with a Δ G (CPCM) of ∼+57 kcal mol –1 for both X = Cl and Br. Thus, Ni 0 is unlikely to be a catalytically relevant redox state.…”

“…Reactions involving electron transfers were corrected by adding the energy of Mn 0/2+ redox couple or TDAE 0/+ , which were used as the external reducing agents in refs and . Note that we have adopted values of E ° = −1.94 V vs Fc +/0 for Mn 2+/0 obtained from the experiments in refs and and E ° = −1.34 V vs Fc +/0 for TDAE +/0 from computations in this article.…”

Electronic Structures of Nickel(II)-Bis(indanyloxazoline)-dihalide Catalysts: Understanding Ligand Field Contributions That Promote C(sp²)–C(sp³) Cross-Coupling

“…In some cases, as seen from Table 1 the value of K f decreases and irreversibility increases in acetonitrile in comparison to water. Since the value of dielectric constant of solvent is very low and again viscosity also decreases regularly, the shifts of E 1/2 to more positive values and the change of i d can be best explained on the basis of salvation and viscosity [15][16][17].…”

Study of Complex Formation Constants for Some Cations With O-Phenylenediamine in Binary Systems Using Square Wave Polarography Technique

“…Together, these calculations and the ligand field spectroscopy both indicate for the first time that the RAMO energy is an excellent descriptor of the redox properties of these metal-based cross-coupling catalysts, and DFT calculations provide a useful approach for analyzing ligand contributions to potentials.Finally, further extending these calculations to additional species, the computed reduction of Ni I (IB)X to Ni 0 (IB)X or Ni 0 (IB) is calculated to occur at exceedingly negative formal potentials (~-3 V to -4 V). These calculated potentials for Ni 0 formation are significantly more negative than the reduction potentials of typical reductants used in cross-coupling reactions (e.g., ~-1.11 V vs.Fc +/0 in DMA for tetrakis(dimethylamino)ethylene (TDAE) or ~-1.94 V vs Fc +/0 in DMF for Mn 0 ) 46,47. Similarly, the disproportionation of Ni I (IB)X to Ni II (IB)X2 and Ni 0 (IB) is thermodynamically highly unfavorable, with a ΔG(CPCM) of ~+57 kcal mol -1 for both X = Cl and Br.…”

Electronic structures of nickel(II)-bis(indanyloxazoline)-dihalide catalysts: Understanding ligand field contributions that promote C(sp2)–C(sp3) cross-coupling