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Synlett 2021; 32(16): 1606-1620
DOI: 10.1055/s-0040-1719829
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Modern Nickel-Catalyzed Reactions

Experimental Electrochemical Potentials of Nickel Complexes

Qiao Lin
,
Gregory Dawson
,
Tianning Diao
This work was supported by the National Science Foundation under Award Number CHE-1654483.
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Abstract

Nickel-catalyzed cross-coupling and photoredox catalytic reactions has found widespread utilities in organic synthesis. Redox processes are key intermediate steps in many catalytic cycles. As a result, it is pertinent to measure and document the redox potentials of various nickel species as precatalysts, catalysts, and intermediates. The redox potentials of a transition-metal complex are governed by its oxidation state, ligand, and the solvent environment. This article tabulates experimentally measured redox potentials of nickel complexes supported on common ligands under various conditions. This review article serves as a versatile tool to help synthetic organic and organometallic chemists evaluate the feasibility and kinetics of redox events occurring at the nickel center, when designing catalytic reactions and preparing nickel complexes.

1 Introduction

1.1 Scope

1.2 Measurement of Formal Redox Potentials

1.3 Redox Potentials in Nonaqueous Solution

2 Redox Potentials of Nickel Complexes

2.1 Redox Potentials of (Phosphine)Ni Complexes

2.2 Redox Potentials of (Nitrogen)Ni Complexes

2.3 Redox Potentials of (NHC)Ni Complexes


#

Key words

redox potentials - nickel - cyclic voltammetry - reduction - oxidation
1

Introduction

1.1

Scope

In recent years, nickel-catalyzed cross-coupling,[1] photoredox-dual catalysis,[2] and electrocatalytic[3] reactions have emerged as versatile tools to enable challenging transformations and construct organic molecules. Reaction development is dependent on delicate design and intricate arrangement of redox-active organonickel species to accomplish the catalytic cycle. A proper selection of the nickel catalyst and the corresponding organic substrates delivers selective electron-transfer processes. The thermodynamic driving force of an outer-sphere electron-transfer event is often estimated by the Gibbs free energy change, which can be calculated by the standard potentials of the donor and the acceptor (ΔG° = –nFE°).

A formal potential, sometimes referred to as a conditional potential, is the reduction potential that applies to a half reaction under a specific set of conditions, as opposed to the standard-state conditions.[4] Nicewicz and co-workers measured and summarized the formal potentials of organic molecules with common functional groups.[5] In this review article, we tabulate the redox potentials of nickel complexes that have been reported in the literature. Since nickel can accommodate oxidation states ranging from 1 to 4+,[6] more than one redox processes can occur at a certain nickel center. We organize nickel complexes according to their isolated oxidation states and indicate the directions of the redox transformations in the ‘process’ column.


# 1.2

Measurement of Formal Redox Potentials

Cyclic voltammetry (CV) is a common tool for determining the formal potential for a redox-active compound.[7] [8] As described by the Nernst equation, the electrode potential (E) is determined by the formal potential (E0′) and the concentrations of the oxidized and reduced analyte, where R is the gas constant, T is the temperature, F is the Faraday's constant, n is the number of electrons transferred, and [ox] and [red] are the concentrations of the oxidized and reduced species, respectively (Equation 1).

Zoom Image
Equation 1

For example, in the CV scan of ferrocene (Fc), an electric potential is applied linearly to the sample (Figure [1]A). The line in the voltammogram is the current passed-per-unit time (Figure [1]B). Current is dependent on the concentration of the substrate at the electrode per unit time, which is determined by the rate of diffusion, caused by the concentration gradient near the electrode. As the potential is scanned in a positive direction, current starts to build and increases from point A to point C, due to the increasingly faster diffusion of Fc to the electrode, as Fc is oxidized to ferrocenium (Fc+) on the electrode surface. The higher the oxidation potential applied to the electrode, the higher the current and higher ratio of [Fc+]/[Fc] till the electrode potential reaches point B, whose potential is E1/2, where [Fc] = [Fc+]. The diffusion rate continues to grow until arriving point C, where the current reaches maximum at point C (Ep). When the applied potential travels from point C to D, [Fc] far away from the electrode starts to deplete and [Fc+] far away from the electrode increases. The current decreases, as the electrooxidation becomes diffusion controlled. At point D, the current converges to the value of ‘diffusion-limited current’.

Zoom Image
Figure 1 (A) Applied potential as a function of time for a generic cyclic voltammetry experiment, with the initial, switching, and end potentials represented (A, D, and G, respectively). (B) Cyclic voltammogram of the reversible oxidation of a 1 mM Fc solution to Fc+, at a scan rate of 100 mV/s.

The same process occurs when scanning Fc in a negative direction, resulting in a reduction peak.[9] For an electrochemically reversible process, E1/2 is determined as the midpoint of anodic and cathodic peak potentials and is typically regarded as the formal potential E0′.[8] For an irreversible CV, when the reverse peak is not observed, the half-peak potential Ep/2, defined as the potential at the half-peak current, is used as an alternative to estimate E0′.[5] Ep/2 values must be considered in the context of the detailed conditions at which the CVs are measured.[5] In this review, we focus on nickel complexes with available E1/2 data.


# 1.3

Redox Potentials in Nonaqueous Solution

Formal potentials (E0′) estimated by averaging the forward and backward peak potentials from reversible redox-active species are documented in this review vs. the Fc/Fc+ couple, as recommended by IUPAC.[10] Aqueous reference electrodes such as saturated calomel electrode (SCE) or saturated Ag/AgCl could cause the generation of liquid junction potentials, a potential difference built up due to the tendency of electrolytes to diffuse between two different solutions, when applied to the organic media. The resulting liquid junction potentials could shift the observed potential from the inherent redox potential to various extents according to the solvent.[11] Table [1] summarizes potentials of the Fc/Fc+ couple, measured in different solvents and with supporting electrolytes.[12] Given the good reproducibility of SCE in nonaqueous solutions, Table [1] can be used to calibrate potentials measured in different solvents and using different electrolytes.

Table 1 Formal Potentials (V) of the Ferrocene/Ferrocenium Redox Couple vs SCE with Selected Electrolytesa

Solvent

TBABF4

TBAPF6

TBAClO4

Et4NPF6

Et4NClO4

Et4NBF4

MeCN

0.39[14]

0.40

0.38

0.38

0.39[15]

DCM

0.46[16]

0.46

0.48

0.49[26]

0.59[17]

THF

0.56

0.53

DMF

0.55[18]

0.45

0.47

0.46

Acetone

0.48

0.50

0.46

PhCN

0.50[19]

0.47[19]

a Supporting electrolyte concentration, 0.1 M. Data are extracted from ref. 12 unless specified otherwise.

In this article, we extract CV data from the literature and convert the potential values of a certain reference electrode into Fc/Fc+ based on Table [1] or the Fc/Fc+ potentials reported in the original paper; the parameters used for the conversion are listed underneath each table. In this regard, we unify the redox potentials to the same reference for direct comparison. As shown in Table [1], the potential of Fc/Fc+ is sensitive to the experimental conditions, such as electrolytes and their concentration, solvent, etc.[13] Thus, it is strongly recommended to specify solvent and electrolyte conditions when reporting CV data against Fc/Fc+.[12]


#
# 2

Redox Potentials of Nickel Complexes

2.1

Redox Potentials of (Phosphine)Ni Complexes

Most phosphine ligands applied to support nickel complexes are strong σ-donors.[20] Table [2] summarizes the one-electron oxidation potentials of (phosphine)Ni(0) or the one-electron reduction of (phosphine)Ni(I) complexes. Redox potentials are directly related to the valence orbitals, sensitive to both the identity of the ligands and the molecular geometry. In general, electron-rich substituents on the ligand framework shift the redox potentials to the negative direction. For example, [PhB(CH2P i Pr2)3]Ni 4 and 6, with a borate on the ligand, have E[Ni(I/0)] as negative as –1.95 V, whereas (B2P2)Ni 27, a complex supported on an electron-deficient borane ligand, has the most positive E[Ni(I/0)] in Table [2]. Outer-sphere counterions, on the other hand, only have subtle impact on the redox potentials. The E[Ni(I/0)] of [HN(P i Pr2)2]2NiX2 (X = NO3 7, ClO4 9, BF4 10) are almost identical. Generally, Ni(I)–aryl and halide complexes exhibit significantly more negative redox potentials than Ni(diphosphine)2 complexes.

Table 2 Formal Potentials of the Ni(I)/Ni(0) Transformation for (Phosphine)Ni Complexes

Complex

Process

Solvent

Electrolyte (M)

Potential reference

E1/2 (V vs. Fc/Fc+)

( tBuXantphos)Ni(2,4-xylene)[21]

 1

Ni(I) → Ni(0)

THF

TBAPF6 (0.4)

Fc/Fc+

–2.78

( tBuXantphos)Ni(o-Tol)[21]

 2

Ni(I) → Ni(0)

THF

TBAPF6 (0.4)

Fc/Fc+

–2.70

(dppb)Ni[(CN)2C2S2][40]

 3

Ni(I) → Ni(0)

DMF

TBABF4 (0.1)

Fc/Fc+

–2.22

[PhB(CH2P i Pr2)3]Ni(PMe3)[22]

 4

Ni(I) → Ni(0)

THF

TBAPF6 (0.35)

Fc/Fc+

–1.95

(acriPNP)Ni(CO)[23]

 5

Ni(I) → Ni(0)

THF

TBAPF6 (0.3)

Fc/Fc+

–1.87

[PhB(CH2PiPr2)3]Ni(CNtBu)[22]

 6

Ni(I) → Ni(0)

THF

TBAPF6 (0.35)

Fc/Fc+

–1.85

[HN(P i Pr2)2]2Ni(NO3)2 [24]

 7

Ni(I) → Ni(0)

THF

TBAPF6 (0.1)

Fc/Fc+

–1.53

Ni(PCy 2N tBu 2)2 [25]

 8

Ni(0) → Ni(I)

PhCN

TBAPF6 (0.2)

Fc/Fc+

–1.49

[HN(P i Pr2)2]2Ni(ClO4)2 [24]

 9

Ni(I) → Ni(0)

THF

TBAPF6 (0.1)

Fc/Fc+

–1.49

[HN(P i Pr2)2]2Ni(BF4)2 [24]

10

Ni(I) → Ni(0)

THF

TBAPF6 (0.1)

Fc/Fc+

–1.45

Ni(dmpp)2 [26]

11

Ni(0) → Ni(I)

MeCN

Et4NBF4 (0.3)

Fc/Fc+

–1.33

Ni(PMe3)4 [27]

12

Ni(0) → Ni(I)

1,2-C6H4F2

TBAPF6 (0.1)

Fc/Fc+

–1.31

(PMe 2NPh 2)2Ni(BF4)2 [28]

13

Ni(I) → Ni(0)

PhCN

TBAPF6 (0.2)

Fc/Fc+

–1.30

Ni(depe)2 [26]

14

Ni(0) → Ni(I)

MeCN

Et4NBF4 (0.3)

Fc/Fc+

–1.29

(PPh 2NMe(CH)Ph 2)2Ni(BF4)2 [29]

15

Ni(I) → Ni(0)

MeCN

TBABF4 (0.1)

Fc/Fc+

–1.27

Ni(NHCMesCH2PCy2)(cod)[30]

16

Ni(0) → Ni(I)

THF

TBAPF6 (0.1)

Fc/Fc+

–1.26

Ni(dppf)2 [31]

17

Ni(0) → Ni(I)

THF

TBAPF6 (0.2)

Fc/Fc+

–1.18

(PPh 2NPh(CH)Ph 2)2Ni(BF4)2 [29]

18

Ni(I) → Ni(0)

MeCN

TBABF4 (0.1)

Fc/Fc+

–1.14

(PPh 2NBn 2)2Ni(BF4)2 [29]

19

Ni(I) → Ni(0)

MeCN

TBABF4 (0.1)

Fc/Fc+

–1.13

(PPh 2N p-Tol 2)2Ni(BF4)2 [29]

20

Ni(I) → Ni(0)

MeCN

TBABF4 (0.1)

Fc/Fc+

–1.08

(triphos)(PEt3)Ni(BF4)2 [32]

21

Ni(I) → Ni(0)

MeCN

Et4NBF4 (0.2)

SCE

–1.05a

Ni(dcype)(cod)[30]

22

Ni(0) → Ni(I)

THF

TBAPF6 (0.1)

Fc/Fc+

–0.95

Ni(dppp)2 [26]

23

Ni(0) → Ni(I)

MeCN

Et4NBF4 (0.3)

Fc/Fc+

–0.91

(triphos)Ni(PPh3)[33]

24

Ni(0) → Ni(I)

THF

TBAPF6 (0.1)

NHE

–0.90b

Ni(dppe)2 [26]

25

Ni(0) → Ni(I)

MeCN

Et4NBF4 (0.3)

Fc/Fc+

–0.88

(dppv)2Ni(BF4)2 [34]

26

Ni(I) → Ni(0)

MeCN

Et4NBF4 (0.3)

Fc/Fc+

–0.83

(B2P2)Ni[35]

27

Ni(0) → Ni(I)

MeCN

TBAPF6 (0.1)

Fc/Fc+

0.06

a Fc = 0.40 V vs SCE (MeCN/Et4NBF4).[32]

b Fc = 0.56 V vs SCE (THF/TBAPF6).[12] Converted into NHE by adding 0.24 V.

Complexes with halide ligands generally do not have reversible reduction CV, due to the fast dissociation of halides. Monodentate phosphine ligands can be labile and may result in geometry reorganization upon oxidation or reduction.[36] The one-electron oxidation of Ni(PMe3)4 12 shows a reversible CV, whereas the following oxidation to Ni(II) is electrochemically quasireversible, reflecting a change of geometry from tetrahedral to square planar.[27] The synthesis of a series of Ni(I) complexes has enabled the measurement of redox potentials starting from the +1 oxidation state. A ( tBuXantphos)Ni(I)–aryl complex 1 exhibits a very negative reversible reduction peak at –2.78 V.[21] In contrast, Ni(I)–bromide and Ni(I)–chloride complexes, supported on an isopropyl phosphine ligand with a dibenzofuran backbone, give irreversible reduction peaks due to the fast halide dissociation.[37]

[(Cy)N(Ph2P)2]Ni(ClO4)2 43 exists as an equilibrium between the tetrahedral and square planar geometries in acetonitrile. Two E[Ni(II/I)] peaks are observed at –0.97 V and –1.77 V, responding to the tetrahedral and the square planar isomers, respectively. This data is consistent with the lower-energy LUMO in a tetrahedral field. Sometimes, the CV data of certain complexes cannot be used to estimate the potentials of their analogues. Bis(diphosphine)Ni complexes exhibit a wide range of redox potentials, from –1.16 V of Ni(depe)2 14 to –0.19 V of Ni(dppp)2 23, responding to the substituents and the chain length between the two phosphines. Dithiolate and catecholate are good electron-donating ligands. E[Ni(II/I)] of [(Me)N(Et2PCH2)2]Ni(C2H4S2) 28 is –2.34 V (Table [3]), whereas that of [(Me)N(Et2PCH2)2]Ni(BF4)2 48 is –0.64 V. With the same spectator ligand, varying the halide down the group shifts the potential to a more positive direction (E[Ni–Cl] < E[Ni–Br] < E[Ni–I], E[Ni–OR] < E[Ni–SR] < [Ni–SeR]).

The two-electron reduction, E[Ni(II/0)], is also observed, in some cases, due to the overlap of two redox events.[50] (Triphos)(P(OMe)3)Ni(BF4)2 shows a two-electron reduction peak at –0.85 V, while its analogue (triphos)(PEt3)Ni(BF4)2 21 gives two sequential one-electron reductions at –0.77 V and –1.05 V.[32] Theoretically, the half-peak separation, |Epa Epc |/2, of the two-electron redox processes should be 30 mV, narrower than that of a one-electron event, 60 mV. Since peak separation is also dependent on kinetics and the resistance, the peak-to-peak separation alone is indefinitive for determining the electron stoichiometry for redox events.[51] Formal potentials for high-valence (phospines)Ni mostly are obtained via oxidation of isolated Ni(II) complexes (Table [4]).

Table 3 Formal Potentials of the Ni(II)/Ni(I) Transformation for (Phosphine)Ni Complexes

Complex

Process

Solvent

Electrolyte (M)

Potential reference

E1/2 (V vs. Fc/Fc+)

[(Me)N(Et2PCH2)2]Ni(C2H4S2)[47]

28

Ni(II) → Ni(I)

MeCN

Et4NBF4 (0.3)

Fc/Fc+

–2.34

(dppe)Ni(3,4-CH3C6H3S2)[38]

29

Ni(II) → Ni(I)

DCM

TBAClO4 (0.1)

Ag/AgCl

–2.05a

[2,6-( t Bu2PCH2)2C6H3]NiCl[39]

30

Ni(II) → Ni(I)

MeCN

TBABF4 (0.1)

NHE

–1.88b

[(cyclohexyl)N(Ph2P)2]2 Ni(ClO4)2 [44]

43

Ni(II) → Ni(I)

MeCN

TBABF4 (0.45)

Fc/Fc+

–1.77c

(dppe)Ni[(CN)2C2S2][38]

31

Ni(II) → Ni(I)

DCM

TBAClO4 (0.1)

Ag/AgCl

–1.66a

( tBuXantphos)Ni(2,4-xylene)[21]

1

Ni(I) → Ni(II)

THF

TBAPF6 (0.4)

Fc/Fc+

–1.59

( tBuXantphos)Ni(o-Tol)[21]

 2

Ni(I) → Ni(II)

THF

TBAPF6 (0.4)

Fc/Fc+

–1.51

[PhB(CH2PPh2)3]Ni(OSiPh3)[22]

32

Ni(II) → Ni(I)

THF

TBAPF6 (0.35)

Fc/Fc+

–1.47

[PhB(CH2P i Pr2)3]NiCl[22]

33

Ni(II) → Ni(I)

THF

TBAPF6 (0.35)

Fc/Fc+

–1.44

(dae)Ni[(CN)2C2S2][38]

34

Ni(II) → Ni(I)

DCM

TBAClO4 (0.1)

Ag/AgCl

–1.44a

(dppb)Ni[(CN)2C2S2][40]

 3

Ni(II) → Ni(I)

DMF

TBABF4 (0.1)

Fc/Fc+

–1.43

[PhB(CH2PPh2)3]Ni(O-p- t Bu-Ph)[22]

35

Ni(II) → Ni(I)

THF

TBAPF6 (0.35)

Fc/Fc+

–1.36

(d t bpe)Ni(CH2CMe3)[41]

36

Ni(I) → Ni(II)

THF

TBAPF6 (0.4)

Fc/Fc+

–1.25

(acriPNP)Ni(CO)[23]

 5

Ni(II) → Ni(I)

THF

TBAPF6 (0.3)

Fc/Fc+

–1.20

[PhB(CH2PPh2)3]NiCl[22]

37

Ni(I) → Ni(II)

THF

TBAPF6 (0.35)

Fc/Fc+

–1.20

(PPh3)2Ni[(CN)2C2S2][38]

38

Ni(II) → Ni(I)

DCM

TBAClO4 (0.1)

Ag/AgCl

–1.20a

[( n Bu)N(Ph2PCH2)2]NiCl2 [42]

39

Ni(II) → Ni(I)

DCM

TBAPF6 (0.1)

Ag/AgCl

–1.18d

Ni(depe)2 [26]

14

Ni(I) → Ni(II)

MeCN

Et4NBF4 (0.3)

Fc/Fc+

–1.16

[(Me4PNP tBu)NiMe](BPh4)[43]

40

Ni(I) → Ni(II)

MeCN

TBAPF6 (0.1)

Fc/Fc+

–1.14

[PhB(CH2PPh2)3]NiI[22]

41

Ni(II) → Ni(I)

THF

TBAPF6 (0.35)

Fc/Fc+

–1.12

[PhB(CH2PPh2)3]Ni(S-p- t Bu-Ph)[22]

42

Ni(II) → Ni(I)

THF

TBAPF6 (0.35)

Fc/Fc+

–1.12

[HN(P i Pr2)2]2Ni(NO3)2 [24]

 7

Ni(II) → Ni(I)

THF

TBAPF6 (0.1)

Fc/Fc+

–1.06

(PMe 2NPh 2)2Ni(BF4) 2 [28]

13

Ni(II) → Ni(I)

PhCN

TBAPF6 (0.2)

Fc/Fc+

–1.01

[HN(P i Pr2)2]2Ni(ClO4)2 [24]

 8

Ni(II) → Ni(I)

THF

TBAPF6 (0.1)

Fc/Fc+

–1.01

[(cyclohexyl)N(Ph2P)2]2 Ni(ClO4)2 [44]

43′

Ni(II) → Ni(I)

MeCN

TBABF4 (0.45)

Fc/Fc+

–0.97e

[HN(P i Pr2)2]2Ni(BF4)2 [24]

10

Ni(II) → Ni(I)

THF

TBAPF6 (0.1)

Fc/Fc+

–0.97

(PPh 2NMe(CH)Ph 2)2Ni(BF4)2 [29]

15

Ni(II) → Ni(I)

MeCN

TBABF4 (0.1)

Fc/Fc+

–0.93

(tdppme)Ni(S tBu)[45]

44

Ni(I) → Ni(II)

DCM

TBAPF6 (0.1)

SCE

–0.93f

Ni(dmpp)2 [26]

11

Ni(I) → Ni(II)

MeCN

Et4NBF4 (0.3)

Fc/Fc+

–0.89

(dppp)NiBr2 [46]

45

Ni(II) → Ni(I)

THF

TBAPF6 (0.1)

Ag/AgNO3

–0.89g

(triphos)(MeCN)Ni(BF4)2 [32]

46

Ni(II) → Ni(I)

MeCN

Et4NBF4 (0.2)

SCE

–0.88h

Ni(PCy 2N tBu 2)2 [25]

 9

Ni(I) → Ni(II)

PhCN

TBAPF6 (0.2)

Fc/Fc+

–0.87

(PPh 2N p-Tol 2)2Ni(BF4)2 [29]

20

Ni(II) → Ni(I)

MeCN

TBABF4 (0.1)

Fc/Fc+

–0.83

(triphos)(PEt3)Ni(BF4)2 [32]

21

Ni(II) → Ni(I)

MeCN

Et4NBF4 (0.2)

SCE

–0.77h

(tdppme)Ni(SPh)[45]

47

Ni(I) → Ni(II)

DCM

TBAPF6 (0.1)

SCE

–0.75f

(PPh 2NPh(CH)Ph 2)2Ni(BF4)2 [29]

18

Ni(II) → Ni(I)

MeCN

TBABF4 (0.1)

Fc/Fc+

–0.72

Ni(dppe)2 [26]

25

Ni(I) → Ni(II)

MeCN

Et4NBF4 (0.3)

Fc/Fc+

–0.70

[(Me)N(Et2PCH2)2]2Ni(BF4)2 [47]

48

Ni(II) → Ni(I)

MeCN

Et4NBF4 (0.3)

Fc/Fc+

–0.64

(tdppme)Ni(SePh)[45]

49

Ni(I) → Ni(II)

DCM

TBAPF6 (0.1)

SCE

–0.64f

(tdppme)NiCl(ClO4)[48]

50

Ni(II) → Ni(I)

MeCN

Et4NClO4 (0.1)

SCE

–0.63i

(tdppme)NiBr(ClO4)[48]

51

Ni(II) → Ni(I)

MeCN

Et4NClO4 (0.1)

SCE

–0.57i

(dppv)2Ni(BF4)2 [34]

26

Ni(II) → Ni(I)

MeCN

Et4NBF4 (0.3)

Fc/Fc+

–0.52

(tdppme)NiI(ClO4)[48]

52

Ni(II) → Ni(I)

MeCN

Et4NClO4 (0.1)

SCE

–0.47i

Ni(PMe3)4 [27]

12

Ni(I) → Ni(II)

1,2-C6H4F2

TBAPF6 (0.1)

Fc/Fc+

–0.33

Ni(dppp)2 [26]

23

Ni(I) → Ni(II)

MeCN

Et4NBF4 (0.3)

Fc/Fc+

–0.19

a Fc = 0.46 V vs Ag/Ag+ 0.1 M LiCl in DCM (DCM/TBAClO4).[38]

b Fc = 0.69 V vs NHE (MeCN/TBABF4).[39]

c E0 for Sp isomer.

d Fc = 0.33 V vs Ag/AgCl (DCM/TBAPF6).[42]

e E0 for Td isomer.

f Fc = 0.46 V vs SCE (DCM/TBAPF6).[12]

g Fc = 0.176 V vs Ag/0.01 M AgNO3 (THF/TBAPF6).[49]

h Fc = 0.40 V vs SCE (MeCN/Et4NBF4).[32]

i Fc = 0.38 V vs SCE (MeCN/Et4NClO4).[48]

Table 4 Formal Potentials of the Ni(III)/Ni(II) and Ni(IV)/Ni(III) Transformations for Selected (Phosphine)Ni Complexes

Complex

Process

Solvent

Electrolyte (0.1 M)

Potential reference

E1/2 (V vs. Fc/Fc+)

(dppe)Ni(3,4- t BuC6H3O2)[38]

53

Ni(II) → Ni(III)

DCM

TBAClO4

Ag/AgCl

–0.25a

(dppb)Ni[(Me)2C2S2][40]

54

Ni(II) → Ni(III)

DCM

TBAPF6

Fc/Fc+

–0.20

(dppb)Ni[(C6H4-p-OMe)2C2S2][40]

55

Ni(II) → Ni(III)

DCM

TBAPF6

Fc/Fc+

–0.15

[o-C6H4(PMe2)2]2NiCl2 [52]

56

Ni(II) → Ni(III)

MeCN

TBABF4

SCE

–0.03b

[o-C6F4(PMe2)2]2NiCl2 [52]

57

Ni(II) → Ni(III)

MeCN

TBABF4

SCE

 0.08b

[o-C6H4(PMe2)2]2NiBr2 [52]

58

Ni(II) → Ni(III)

MeCN

Et4NClO4

SCE

 0.10c

(dppe)Ni(o-C6Cl4O2)[38]

59

Ni(II) → Ni(III)

DCM

TBAClO4

Ag/AgCl

 0.25a

(dcpf)NiCl2 [53]

60

Ni(II) → Ni(III)

DCM

TBAPF6

Fc/Fc+

 0.30

[2,6-( t Bu2PO)2C6H3]NiH[54]

61

Ni(II) → Ni(III)

MeCN–THF

TBABF4

Fc/Fc+

 0.33

(dppe)NiCl3 [55]

62

Ni(III) → Ni(II)

MeCN

TBAPF6

Fc/Fc+

 0.40

[2,6-( i Pr2PO)2C6H3]Ni(OAc)[56]

63

Ni(II) → Ni(III)

DCM

TBAPF6

Fc/Fc+

 0.43

[2,6-(Ph2PO)2C6H3]Ni(OAc)[56]

64

Ni(II) → Ni(III)

DCM

TBAPF6

Fc/Fc+

 0.55

[( t Bu2PO)2C6H3]NiCl[54]

65

Ni(II) → Ni(III)

MeCN–THF

TBABF4

Fc/Fc+

 0.72

[2,6-( t Bu2PO)2C6H3]NiBr[57]

66

Ni(II) → Ni(III)

DCM

TBAPF6

Fc/Fc+

 0.75

[2,6-(Ph2PO)2C6H3]Ni(OTf)[56]

67

Ni(II) → Ni(III)

DCM

TBAPF6

Fc/Fc+

 0.81

[2,6-( i Pr2PO)2C6H3]Ni(OTf)[56]

68

Ni(II) → Ni(III)

DCM

TBAPF6

Fc/Fc+

 0.98

(dppb)Ni[(Me)2C2S2][40]

54

Ni(III) → Ni(IV)

DCM

TBAPF6

Fc/Fc+

 0.50d

(dppb)Ni[(C6H4-p-OMe)2C2S2][40]

55

Ni(III) → Ni(IV)

DCM

TBAPF6

Fc/Fc+

 0.44

[o-C6H4(PMe2)2]2NiCl2 [52]

56

Ni(III) → Ni(IV)

MeCN

TBABF4

SCE

 0.79b

[o-C6H4(PMe2)2]2NiBr2 [52]

58

Ni(III) → Ni(IV)

MeCN

Et4NClO4

SCE

 0.84c

[o-C6H4(AsMe2)2]2NiCl2 [52]

69

Ni(III) → Ni(IV)

MeCN

Et4NClO4

SCE

 0.91c

[o-C6F4(PMe2)2]2NiCl2 [52]

57

Ni(III) → Ni(IV)

MeCN

TBABF4

SCE

 1.01b

a Fc = 0.46 V vs Ag/Ag+ 0.1 M LiCl in DCM (DCM/TBAClO4).[38]

b Fc = 0.39 V vs SCE (MeCN/TBABF4).[14]

c Fc = 0.38 V vs SCE (MeCN/Et4NClO4).[48]

d Potentials estimated from differential pulse voltammetry by width-at-half-height analysis.


# 2.2

Redox Potentials of (Nitrogen)Ni Complexes

Ni-catalyzed cross-coupling reactions proceeding through radical pathways has benefited from various bidentate and tridentate N-ligands, including bipyridine (bpy), bioxazoline (biOx), terpyridine (terpy), pyridine-oxazoline­ (pyox), and pyridine-bioxazoline (pybox).[6] [58] N-Ligands are π-acceptors and generally stronger σ-donors than phosphines.[59] The redox activity of π-acceptor ligands greatly contributes to the stability of radical complexes. Redox processes may occur on the ligand rather than the metal center. Data in Table [5] and Table [6] refer to the formal oxidation state of the nickel complexes, but do not distinguish the change of oxidation state due to ligand redox activity.

Table 5 Formal Potentials of the Ni(I)/Ni(0) Transformation for Selected Ni/Nitrogen Complexes

Complex

Process

Solvent

Electrolyte (0.1 M)

Potential reference

E1/2 (V vs. Fc/Fc+)

[(–)-i-Pr-pybox]Ni(Ph)B(ArF)4 [60]

70

Ni(I) → Ni(0)

THF

TBAPF6

Fc/Fc+

–2.36

(dtbbpy)(CProp2C)Ni(PF6)2 [61]

71

Ni(I) → Ni(0)

MeCN

TBAPF6

Fc/Fc+

–2.06

(bpy)(CProp2C)Ni(PF6)2 [61]

72

Ni(I) → Ni(0)

MeCN

TBAPF6

Fc/Fc+

–2.00

(Prbimiiql)Ni(PF6)2 [62]

73

Ni(I) → Ni(0)

MeCN

TBAPF6

SCE

–1.60a

(6,6′-Mebpy)NiBr2 [63]

74

Ni(I) → Ni(0)

MeCN

TBABF4

SCE

–1.56b

(DippBIAN)NiCl2 [64]

75

Ni(I) → Ni(0)

MeCN

TBABF4

Fc/Fc+

–1.52

(DippBIAN)NiBr2 [64]

76

Ni(I) → Ni(0)

MeCN

TBABF4

Fc/Fc+

–1.47

(DippBIAN)NiI2 [64]

77

Ni(I) → Ni(0)

MeCN

TBABF4

Fc/Fc+

–1.46

(DippBIAN)Ni(NCMe)4(BF4)2 [64]

78

Ni(I) → Ni(0)

MeCN

TBABF4

Fc/Fc+

–1.45

(DippNPyNDippN)NiCl2 [65]

79

Ni(I) → Ni(0)

MeCN

TBAPF6

Fc/Fc+

–1.23

(DippNPyNDippN)NiBr2 [65]

80

Ni(I) → Ni(0)

MeCN

TBAPF6

Fc/Fc+

–1.22

(bpy)Ni(cod)[30]

81

Ni(0) → Ni(I)

THF

TBAPF6

Fc/Fc+

–1.17

(2-OMe-Ph-Me2DAB)(Cp)NiBF4 [66]

82

Ni(I) → Ni(0)

MeCN

TBAPF6

Fc/Fc+

–1.17

(Ph-Me2DAB)(Cp)NiBF4 [66]

83

Ni(I) → Ni(0)

MeCN

TBAPF6

Fc/Fc+

–1.05

(2-CF3-Ph-Me2DAB)(Cp)NiBF4 [66]

84

Ni(I) → Ni(0)

MeCN

TBAPF6

Fc/Fc+

–0.80

a Fc = 0.40 V vs SCE (MeCN/TBAPF6).[12]

b Fc = 0.38 V vs SCE (MeCN/TBABF4).[63]

The electronic effect of ligands on the redox potential is evident by comparing a series of (4,4′-Mebpy)Ni (4,4′-Mebpy = 92), (bpy)Ni (bpy = 95), and DAB(Ni) (DAB = 105) complexes (Table [6]). The first reduction of Ni(II) complexes can be ligand centered, depending on the coordination number, geometry, and the ligand. For example, the first electron reduction of (dtbbpy)(CProp2C)Ni(PF6)2 71 and (bpy)(CProp2C)Ni(PF6)2 72 is ligand centered, and the second electron reduction is metal centered.[61] The nature of ligands can affect the reversibility of CV. Halides can easily dissociate upon reduction and give rise to irreversible CVs. Terpy complex 104 shows a reversible CV at room temperature, but the CVs of bidentate nitrogen-ligated Ni(Mes)Br complexes in Table [6] were measured at –60 °C to prevent bromide dissociation.[69]

Table 6 Formal Potentials of the Ni(II)/Ni(I) Transformation for (Nitrogen)Ni Complexes

Complex

Process

Solvent

Electrolyte (0.1 M)

Potential reference

E1/2 (V vs. Fc/Fc+)

(bme-daco)Ni[67]

 85

Ni(II) → Ni(I)

MeCN

TBAPF6

NHE

–2.58a

(en)Ni(acac)2 [68]

 86

Ni(II) → Ni(I)

DMF

TBAClO4

SCE

–2.57b

(3,4,7,8-tmphen)Ni(Mes)2 [69]

 87

Ni(II) → Ni(I)

DMF

TBAPF6

Fc/Fc+

–2.22

(Phbpy)Ni(CF3) [70]

 88

Ni(II) → Ni(I)

THF

TBAPF6

Fc/Fc+

–2.04

(bpy)Ni(Mes)2 [69]

 89

Ni(II) → Ni(I)

DMF

TBAPF6

Fc/Fc+

–2.02

(cyclam)NiBr2 [71]

 90

Ni(II) → Ni(I)

DMF

TBABF4

Fc/Fc+

–2.00

(Phbpy)NiBr[70]

 91

Ni(II) → Ni(I)

THF

TBAPF6

Fc/Fc+

–1.90

(4,4′-Mebpy)Ni(Mes)Br[69]

 92

Ni(II) → Ni(I)

DMF

TBAPF6

Fc/Fc+

–1.87

(cyclam)Ni(BF4)2 [71]

 93

Ni(II) → Ni(I)

DMF

TBABF4

Fc/Fc+

–1.85

(Me-bme-daco)NiI[67]

 94

Ni(II) → Ni(I)

MeCN

TBAPF6

NHE

–1.84a

(bpy)Ni(Mes)Br[69]

 95

Ni(II) → Ni(I)

DMF

TBAPF6

Fc/Fc+

–1.79

(α,α′-Me2salen)Ni[72]

 96

Ni(II) → Ni(I)

DMF

TBAClO4

Fc/Fc+

–1.71

(bpy)Ni(Fmes)Br[69]

 97

Ni(II) → Ni(I)

THF

TBAPF6

Fc/Fc+

–1.68

(saltMe)Ni[72]

 98

Ni(II) → Ni(I)

DMF

TBAClO4

Fc/Fc+

–1.67

(salen)Ni[72]

 99

Ni(II) → Ni(I)

DMF

TBAClO4

Fc/Fc+

–1.60

(dtbbpy)(CProp2C)Ni(PF6)2 [61]

 71

Ni(II) → Ni(I)

MeCN

TBAPF6

Fc/Fc+

–1.59

(terpy)2Ni(PF6)2 [73]

100

Ni(II) → Ni(I)

MeCN

TBAClO4

SCE

–1.58c

(bpy)NiCl2 [74]

101

Ni(II) → Ni(I)

DMF

TBAPF6

Ag/AgCl

–1.52d

(bpy)(CProp2C)Ni(PF6)2 [61]

 72

Ni(II) → Ni(I)

MeCN

TBAPF6

Fc/Fc+

–1.50

(bpz)Ni(Mes)2 [69]

102

Ni(II) → Ni(I)

DMF

TBAPF6

Fc/Fc+

–1.48

(bpym)Ni(Mes)Br[69]

103

Ni(II) → Ni(I)

DMF

TBAPF6

Fc/Fc+

–1.47

(terpy)Ni(Mes)Br[69]

104

Ni(II) → Ni(I)

DMF

TBAPF6

Fc/Fc+

–1.45

[(–)-i-Pr-pybox]Ni(Ph)B(ArF)4 [60]

 70

Ni(II) → Ni(I)

THF

TBAPF6

Fc/Fc+

–1.37

(i-Pr-DAB)Ni(Mes)Br[69]

105

Ni(II) → Ni(I)

DMF

TBAPF6

Fc/Fc+

–1.37

(Cl2-saltMe)Ni[72]

106

Ni(II) → Ni(I)

DMF

TBAClO4

Fc/Fc+

–1.37

(trans-III-Me4-cyclam)Ni(ClO4)2 [75]

107

Ni(II) → Ni(I)

MeCN

TBABF4

Ag/AgNO3

–1.36e

(bpz)Ni(Mes)Br[69]

108

Ni(II) → Ni(I)

DMF

TBAPF6

Fc/Fc+

–1.34

(Bz2-bme-daco)NiBr2 [67]

110

Ni(II) → Ni(I)

MeCN

TBAPF6

NHE

–1.31a

(saloph-Cl2)Ni[72]

109

Ni(II) → Ni(I)

DMF

TBAClO4

Fc/Fc+

–1.30

(6,6′-Mebpy)NiBr2 [63]

 74

Ni(II) → Ni(I)

MeCN

TBABF4

SCE

–1.26

(trans-I-Me4-cyclam)Ni(ClO4)2 [75]

111

Ni(II) → Ni(I)

MeCN

TBABF4

Ag/AgNO3

–1.23e

(bpm)Ni(Mes)Br[69]

112

Ni(II) → Ni(I)

DMF

TBAPF6

Fc/Fc+

–1.20

(Prbimiiql)Ni(PF6)2 [62]

 73

Ni(II) → Ni(I)

MeCN

TBAPF6

SCE

–1.14f

(Me2-bme-daco)NiI2 [67]

113

Ni(II) → Ni(I)

MeCN

TBAPF6

NHE

–1.12a

(DippBDI)Ni(η2-O2) [76]

114

Ni(II) → Ni(I)

THF

TBAPF6

Fc/Fc+

–0.98

(DippBIAN)NiCl2 [64]

 75

Ni(II) → Ni(I)

MeCN

TBABF4

Fc/Fc+

–0.97

(DippNPyNDippN)NiCl2 [65]

 79

Ni(II) → Ni(I)

MeCN

TBAPF6

Fc/Fc+

–0.86

(DippBIAN)NiBr2 [64]

 76

Ni(II) → Ni(I)

MeCN

TBABF4

Fc/Fc+

–0.81

(DippBIAN)NiI2 [64]

 77

Ni(II) → Ni(I)

MeCN

TBABF4

Fc/Fc+

–0.80

(DippBIAN)Ni(NCMe)4(BF4)2 [64]

 78

Ni(II) → Ni(I)

MeCN

TBABF4

Fc/Fc+

–0.77

(bpy)Ni(cod) [30]

 81

Ni(I) → Ni(II)

THF

TBAPF6

Fc/Fc+

–0.76

(DippNPyNDippN)NiBr2 [65]

 80

Ni(II) → Ni(I)

MeCN

TBAPF6

Fc/Fc+

–0.68

a Fc = 0.64 V vs NHE (MeCN/TBAPF6).[12]

b Fc = 0.47 V vs SCE (DMF/TBAClO4).[12]

c Fc = 0.38 V vs SCE (MeCN/TBAClO4).[12]

d Fc = 0.50 V vs Ag/0.1 M NaCl (DMF).[72]

e Fc = 0.037 V vs Ag/0.1 M AgNO3 (MeCN/TBAPF6).[77]

f Fc = 0.40 V vs SCE (MeCN/TBAPF6).[12]

Ligand effects in the oxidation of Ni(II) to Ni(III) states follow the typical trend: electron-withdrawing para substituents of the NCN pincer ligand shift the oxidation potential to the positive direction: E[Ni–NH2 117] < E[Ni–OMe 121] < E[Ni–H 123] < E[Ni–Cl 126] < E[Ni–Ac 127] (Table [7]). The reduction potentials of (porphyrin)Ni(III) complexes also reflect the electronic trend of the ligands. Reduction requires a more negative potential for complexes with electron-donating substitutions: E[(T t BuP)Ni 132] < E[(T i PrP)Ni 133] < E[(TEtPrP)Ni 134] < E[(T i BuP)Ni 137] < E[(TPP)Ni 138].[86]

Table 7 Formal Potentials of Ni(III)/Ni(II) and Ni(IV)/Ni(III) Transformations for Selected (Nitrogen)Ni Complexes

Complex

Process

Solvent

Electrolyte (M)

Potential reference

E1/2 (V vs. Fc/Fc+)

(N tBu 2PyPh)Ni(MeCN)2PF6 [78]

115

Ni(II) → Ni(III)

MeCN

TBABF4 (0.1)

Fc/Fc+

–0.66

(N tBu 2PyPh)NiBr(MeCN)PF6 [78]

116

Ni(III) → Ni(II)

MeCN

TBABF4 (0.1)

Fc/Fc+

–0.65

[2,6-(Me2NCH2)2-(4-NH2)C6H2]NiBr[79]

117

Ni(II) → Ni(III)

DCM

TBABr (0.1)

Ag/AgCI

–0.45a

(N tBu 2Py2)Ni(p-F-Ph)Cl[80]

118

Ni(II) → Ni(III)

MeCN

TBAClO4 (0.1)

Fc/Fc+

–0.45

[2,6-(Me2NCH2)2C6H3]NiCl2 [81]

119

Ni(III) → Ni(II)

Acetone

TBACl (0.1)

Ag/AgCl

–0.44b

(Tp)(Cp)Ni(PF6)[82]

120

Ni(II) → Ni(III)

DCM

TBAPF6 (0.1)

Fc/Fc+

–0.42

[2,6-(Me2NCH2)2-(4-OMe)C6H2]NiBr[79]

121

Ni(II) → Ni(III)

DCM

TBABr (0.1)

Ag/AgI

–0.40a

(N tBu 2Py2)Ni(p-F-Ph)Br[80]

122

Ni(II) → Ni(III)

MeCN

TBAClO4 (0.1)

Fc/Fc+

–0.40

[2,6-(Me2NCH2)2C6H3]NiBr[79]

123

Ni(II) → Ni(III)

DCM

TBABr (0.1)

Ag/AgI

–0.39a

(Tp)(Cp*)Ni(PF6)[82]

124

Ni(II) → Ni(III)

DCM

TBAPF6 (0.1)

Fc/Fc+

–0.39

[2,6-(Me2NCH2)2C6H3]Ni(NO3)2 [81]

125

Ni(III) → Ni(II)

Acetone

TBACl (0.1)

Ag/AgCl

–0.38b

[2,6-(Me2NCH2)2-(4-Cl)C6H2]NiBr[79]

126

Ni(II) → Ni(III)

DCM

TBABr (0.1)

Ag/AgI

–0.33a

[2,6-(Me2NCH2)2-(4-Ac)C6H2]NiBr[79]

127

Ni(II) → Ni(III)

DCM

TBABr (0.1)

Ag/AgI

–0.32a

(Phbpy)Ni(CF3)[70]

88

Ni(II) → Ni(III)

THF

TBAPF6 (0.1)

Fc/Fc+

–0.08

(dtbbpy)Ni(C4F8)[83]

128

Ni(II) → Ni(III)

MeCN

TBABF4 (0.1)

Fc/Fc+

–0.02

(Phbpy)NiBr[70]

 91

Ni(II) → Ni(III)

THF

TBAPF6 (0.1)

Fc/Fc+

0.08

(TACN)2Ni(ClO4)3 [84]

129

Ni(III) → Ni(II)

MeCN

TBAClO4 (0.1)

Fc/Fc+

0.56

(Me2Ac2Me2malen)Ni[85]

130

Ni(II) → Ni(III)

MeCN

TBABF4 (0.1)

Ag/AgNO3

0.57c

(Me2Ac2H2malen)Ni[85]

131

Ni(II) → Ni(III)

MeCN

TBABF4 (0.1)

Ag/AgNO3

0.68c

(bpy)Ni(Fmes)Br[69]

 97

Ni(II) → Ni(III)

DCM

TBAPF6 (0.1)

Fc/Fc+

0.81

(Bz2-bme-daco)NiBr2 [67]

109

Ni(II) → Ni(III)

MeCN

TBAPF6 (0.1)

NHE

0.93d

(Me2-bme-daco)NiI2 [67]

113

Ni(II) → Ni(III)

MeCN

TBAPF6 (0.1)

NHE

0.93d

(T t BuP)Ni[86]

132

Ni(II) → Ni(III)

PhCN

TBAClO4 (0.1)

SCE

1.08e

(T i PrP)Ni[86]

133

Ni(II) → Ni(III)

PhCN

TBAClO4 (0.1)

SCE

1.14e

(trans-III-Me4-cyclam)Ni(ClO4)2 [75]

107

Ni(II) → Ni(III)

MeCN

TBABF4 (0.1)

Ag/AgNO3

1.18c

(trans-I-Me4-cyclam)Ni(ClO4)2 [75]

111

Ni(II) → Ni(III)

MeCN

TBAClO4 (0.1)

Ag/AgNO3

1.23c

(TEtPrP)Ni[86]

134

Ni(II) → Ni(III)

PhCN

TBABF4 (0.1)

SCE

1.23e

(bpy)3Ni(BF4)2 [87]

135

Ni(II) → Ni(III)

MeCN

TBABF4 (0.1)

Fc/Fc+

1.23

(terpy)2Ni(PF6)2 [73]

100

Ni(II) → Ni(III)

MeCN

TBAClO4 (0.1)

SCE

1.27f

(bpy)3Ni(ClO4)2 [88]

136

Ni(II) → Ni(III)

MeCN

TBAClO4 (0.2)

SCE

1.30f

(T i BuP)Ni[86]

137

Ni(II) → Ni(III)

PhCN

TBAClO4 (0.1)

SCE

1.32e

(TPP)Ni[86]

138

Ni(II) → Ni(III)

PhCN

TBAClO4 (0.1)

SCE

1.33e

(bpy)2Ni[88]

139

Ni(II) → Ni(III)

MeCN

TBAClO4 (0.2)

SCE

1.34f

(OEP)Ni[86]

140

Ni(II) → Ni(III)

PhCN

TBAClO4 (0.1)

SCE

1.38e

(Tp)Ni(CF3)3 [89]

141

Ni(IV) → Ni(III)

MeCN

TBAPF6 (0.1)

SCE

–0.80g

(NMe 2Py2)NiMe2(PF6) [90]

142

Ni(III)→ Ni(IV)

MeCN

TBAPF6 (0.1)

Fc/Fc+

–0.03

(NMe 2Py2)Ni(cycloneophyl)(PF6)[90]

143

Ni(III)→ Ni(IV)

MeCN

TBAPF6 (0.1)

Fc/Fc+

0.21

(Tp)(Cp)Ni(PF6)[82]

120

Ni(III)→ Ni(IV)

DCM

TBAPF6 (0.1)

Fc/Fc+

0.44

[2,6-(Me2NCH2)2C6H3]NiBr2 [91]

144

Ni(III)→ Ni(IV)

MeCN

TBAPF6 (0.1)

Fc/Fc+

0.69

(dtbbpy)Ni(C4F8)[83]

128

Ni(III)→ Ni(IV)

MeCN

TBABF4 (0.1)

Fc/Fc+

1.16

(bpy)3Ni(BF4)2 [87]

135

Ni(III)→ Ni(IV)

MeCN

TBABF4 (0.1)

Fc/Fc+

1.98

a Fc = 0.87 V vs Ag/AgI (0.4 M TBAClO4 and 0.05 M TBAI in DCM) (DCM/TBABr).[79]

b Fc = 0.63 V vs Ag/Ag+ 0.1 M LiCl in acetone (acetone/TBACl).[81]

c Fc = 0.037 V vs Ag/0.1 M AgNO3 (MeCN/TBAPF6).[77]

d Fc = 0.64 V vs NHE (MeCN/TBAPF6).[12]

e Fc = 0.50 V vs SCE (PhCN/TBAClO4).[19]

f Fc = 0.38 V vs SCE (MeCN/TBAClO4).[12]

g Fc = 0.40 V vs SCE (MeCN/TBAPF6).[12]


# 2.3

Redox Potentials of (NHC)Ni Complexes

The use of N-heterocyclic carbenes (NHC) in homogeneous nickel catalysis has dramatically expanded over the past two decades as a modular, strongly σ-donating, and nonlabile alternative to phosphines.[20] (NHC)Ni complexes have found a wide range of applications in cross-coupling reactions, in which nickel is stabilized in both open and closed-shell electron configurations.[20] [92] A wide range of oxidation states can be supported on (NHC)Ni complexes. Data collected in Table [8], Table [9], and Table [10] cover single-electron transformations from Ni(0) up to Ni(IV). As a strong σ-donor, NHC drastically shifts the redox potentials of nickel complexes to the negative direction. E[Ni(I/0)] of 145 is as negative as –2.50 V. Nickel(0) complexes carrying more NHC ligands, or electron-donating substituents, are oxidized at a more negative potential (Table [8]). The better σ-donor (SIPr)Ni(0) 153 is oxidized at a more negative potential relative to (IPr)Ni(0) 154.

In summary, we tabulate the redox potentials of nickel complexes experimentally measured by CV and convert data to a unified Fc/Fc+ reference electrode for direct comparison. The redox potentials are clearly determined by the oxidation state, the electronic effect of the ligand, the coordination geometry, the solvent, and the electrolyte conditions. This article is meant to assist synthetic organic and organometallic chemists to evaluate the feasibility and kinetics of redox events occurring at the nickel center, when designing catalytic reactions and preparing nickel complexes.

Table 8 Formal Potentials of the Ni(I)/Ni(0) Transformation for Selected (NHC)Ni Complexes

Complex

Process

Solvent

Electrolyte (0.1 M)

Potential reference

E1/2 (V vs. Fc/Fc+)

(TIMEN tBu)Ni[93]

145

Ni(0) → Ni(I)

THF

TBAClO4

Fc/Fc+

–2.50

(IPr)Ni(NHDipp)[94]

146

Ni(I) → Ni(0)

THF

TBAPF6

Fc/Fc+

–2.41

(SPMes)2NiBr[95]

147

Ni(I) → Ni(0)

THF

TBAPF6

NHE

–2.12a

(IMes)2Ni[96]

148

Ni(0) → Ni(I)

THF

TBAPF6

Fc/Fc+

–1.90

(MeCPropCMe)Ni(dtbbpy)(PF6)2 [61]

149

Ni(I) → Ni(0)

MeCN

TBAPF6

Fc/Fc+

–1.85

(MeCPropCMe)Ni(bpy)(PF6)2 [61]

150

Ni(I) → Ni(0)

MeCN

TBAPF6

Fc/Fc+

–1.79

(Prbimiql)Ni(PF6)2 [62]

151

Ni(I) → Ni(0)

MeCN

TBAPF6

SCE

–1.78b

(Prbzbimpy)Ni(PF6)2 [62]

152

Ni(I) → Ni(0)

MeCN

TBAPF6

SCE

–1.62b

(SIPr)Ni(Cp)[97]

153

Ni(0) → Ni(I)

THF

TBAPF6

Fc/Fc+

–0.75

(IPr)Ni(Cp)[98]

154

Ni(0) → Ni(I)

THF

TBAPF6

Fc/Fc+

–0.66

I i Pr(bzim)Ni(Cp)[98]

155

Ni(0) → Ni(I)

DCM

TBA[B(ArF 4)]

Fc/Fc+

 0.22

(benzo)I i Pr(bzim)Ni(Cp)[99]

156

Ni(0) → Ni(I)

DCM

TBA[B(ArF 4)]

Fc/Fc+

 0.27

IMe(bzim)Ni(Cp)[99]

157

Ni(0) → Ni(I)

DCM

TBA[B(ArF 4)]

Fc/Fc+

 0.32

(benzo)IMe(bzim)Ni(Cp)[99]

158

Ni(0) → Ni(I)

DCM

TBA[B(ArF 4)]

Fc/Fc+

 0.40

a Fc = 0.80 V vs NHE (THF/TBAPF6).[12]

b Fc = 0.40 V vs SCE (MeCN/TBAPF6).[12]

Table 9 Formal Potentials of the Ni(II)/Ni(I) Transformation for Selected (NHC)Ni Complexes

Complex

Process

Solvent

Electrolyte (0.1 M)

Potential reference

E 1/2 (V vs. Fc/Fc+)

[(benzo)I(CH2Py)2]2NiBr2 [100]

159

Ni(II) → Ni(I)

DMF

TBAPF6

Ag/AgCl

–1.56a

(MeCPropCMe)Ni(dtbbpy)(PF6)2 [61]

149

Ni(II) → Ni(I)

MeCN

TBAPF6

Fc/Fc+

–1.54

[(benzo)I(CH2Py)(Bz)]2NiBr2 [99]

160

Ni(II) → Ni(I)

DMF

TBAPF6

Ag/AgCl

–1.51a

(IMes)(Cp)NiCl[100]

161

Ni(II) → Ni(I)

MeCN

TBABF4

NHE

–1.51b

(MeCPropCMe)Ni(bpy)(PF6)2 [61]

150

Ni(II) → Ni(I)

MeCN

TBAPF6

Fc/Fc+

–1.42

(Prbimiql)Ni(PF6)2 [62]

151

Ni(II) → Ni(I)

MeCN

TBAPF6

SCE

–1.32c

(IPr)Ni(Cp*)[101]

162

Ni(I) → Ni(II)

THF

TBAPF6

Fc/Fc+

–1.18

(Prbzbimpy)Ni(PF6)2 [62]

152

Ni(II) → Ni(I)

MeCN

TBAPF6

SCE

–1.03c

(TIMEN tBu)Ni[94]

145

Ni(I) → Ni(II)

THF

TBAClO4

Fc/Fc+

–1.09

(IMes)Ni(Cp)[102]

163

Ni(I) → Ni(II)

THF

TBAPF6

Fc/Fc+

–1.06

(IPr)Ni(Cp)[102]

154

Ni(I) → Ni(II)

THF

TBAPF6

Fc/Fc+

–1.02

(IPr)Ni(NHDipp)[95]

146

Ni(II) → Ni(I)

THF

TBAPF6

Fc/Fc+

–0.84

(I n Bu)(Cp)NiBr[102]

164

Ni(II) → Ni(I)

DCM

TBAPF6

SCE

 0.22d

(pyrene-I n Bu)(Cp)NiBr[103]

165

Ni(II) → Ni(I)

DCM

TBAPF6

SCE

 0.22d

(benzo-I n Bu)(Cp)NiBr[103]

166

Ni(II) → Ni(I)

DCM

TBAPF6

SCE

 0.24d

a Fc = 0.51 V vs Ag/AgCl (DMF/TBAPF6).[100]

b Fc = 0.69 V vs NHE (MeCN/TBABF4).[101]

c Fc = 0.40 V vs SCE (MeCN/TBAPF6).[12]

d Fc = 0.44 V vs SCE (DCM/TBAPF6).[103]

Table 10 Formal Potentials of the Ni(III)/Ni(II) and Ni(IV)/Ni(III) Transformations for Selected (NHC)Ni Complexes

Complex

Process

Solvent

Electrolyte (0.1 M)

Potential reference

E 1/2 (V vs. Fc/Fc+)

(IPr)Ni(S2C2Ph2)(MeCN)[103]

167

Ni(II) → Ni(III)

DCM

TBAPF6

Fc/Fc+

–0.13

(IMe)(Cp)NiI[101]

168

Ni(II) → Ni(III)

MeCN

TBABF4

NHE

–0.13a

(IMes)(Cp)NiCl[101]

161

Ni(II) → Ni(III)

MeCN

TBABF4

NHE

 0.03a

[I(2-oxy-3,5- t Bu2Ph)]Ni(Py)[104]

169

Ni(II) → Ni(III)

DCM

TBAPF6

Fc/Fc+

 0.10

( iPrCNN)Ni(CCPh)[105]

170

Ni(II) → Ni(III)

DCM

TBAPF6

Fc/Fc+

 0.21

trans-[(IMes)2NiF(2,3,5-F-Ph)][97]

171

Ni(II) → Ni(III)

MeCN

TBAPF6

Fc/Fc+

 0.40

(DIPPCCC)NiCl[106]

172

Ni(II) → Ni(III)

DCM

TBAPF6

Fc/Fc+

 0.57

[(benzo)I(2-oxy-3,5- t Bu2Ph)]Ni(Py)[105]

173

Ni(II) → Ni(III)

DCM

TBAPF6

Fc/Fc+

 0.71

[I(2-oxy-3,5- t Bu2Ph)]Ni(Py)[105]

169

Ni(III) → Ni(IV)

DCM

TBAPF6

Fc/Fc+

 0.70

[(benzo)I(2-oxy-3,5- t Bu2Ph)]Ni(Py)[105]

173

Ni(III) → Ni(IV)

DCM

TBAPF6

Fc/Fc+

 1.30

a Fc = 0.69 V vs NHE (MeCN/TBABF4).[101]


#
#
#

Conflict of Interest

The authors declare no conflict of interest.

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Corresponding Author

Tianning Diao
Department of Chemistry, New York University
100 Washington Square East, New York, NY 10003
USA   
Email: diao@nyu.edu

Publication History

Received: 21 July 2021

Accepted after revision: 10 August 2021

Article published online:
26 August 2021

© 2021. Thieme. All rights reserved

Georg Thieme Verlag KG
Rüdigerstraße 14, 70469 Stuttgart, Germany

  • References

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Zoom Image
Equation 1
Zoom Image
Figure 1 (A) Applied potential as a function of time for a generic cyclic voltammetry experiment, with the initial, switching, and end potentials represented (A, D, and G, respectively). (B) Cyclic voltammogram of the reversible oxidation of a 1 mM Fc solution to Fc+, at a scan rate of 100 mV/s.