Systematic Electronic Tuning on the Property and Reactivity of Cobalt–(Hydro)peroxo Intermediates

Kim, Kyungmin; Oh, Sang Wook; Jeong, Donghyun; Lee, Yuri; Moon, Dohyun; Lee, Sunggi; Cho, Jaeheung

doi:10.1021/acs.inorgchem.3c00826

Cited by 3 publications

(9 citation statements)

References 62 publications

(97 reference statements)

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“…The significantly different p K a values could be mainly rationalized by the compression of Co–N ax distances in Me 3 -TPADP for the peroxo case, which could explain its higher basicity due to a strong ligand field. 44 , 57 Furthermore, the decreased redox potential of 2 (0.12 V vs Fc +/0 ) compared to that of 2 TBDAP (0.24 V vs Fc +/0 ) indicated that 2 was a more electron-rich complex ( Figure S24 ), 73 which was consistent with the previous studies that reported the decreases in redox potential values by the introduction of less bulky ligands. 50 − 53 These results were further supported by DFT calculations (vide infra).…”

Section: Resultssupporting

confidence: 89%

“…The p K a value of 2 was estimated as 7.7, which was higher than that of 2 TBDAP (p K a = 2.1) (Figures S22 and S23). The significantly different p K a values could be mainly rationalized by the compression of Co–N ax distances in Me 3 -TPADP for the peroxo case, which could explain its higher basicity due to a strong ligand field. , Furthermore, the decreased redox potential of 2 (0.12 V vs Fc +/0 ) compared to that of 2 TBDAP (0.24 V vs Fc +/0 ) indicated that 2 was a more electron-rich complex (Figure S24), which was consistent with the previous studies that reported the decreases in redox potential values by the introduction of less bulky ligands. − These results were further supported by DFT calculations (vide infra). Thus, the substantially different p K a values and redox potentials of 2 and 2 TBDAP clearly illustrated that the control of basicity by ligand substitution greatly affected the nucleophilicity of the corresponding cobalt(III)–hydroperoxo complexes and regulated the reactivity of nitrile activation.…”

Section: Resultssupporting

confidence: 89%

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Mechanistic Insights into Nitrile Activation by Cobalt(III)–Hydroperoxo Intermediates: The Influence of Ligand Basicity

Son,

Jeong,

Kim

et al. 2023

JACS Au

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The versatile applications of nitrile have led to the widespread use of nitrile activation in the synthesis of pharmacologically and industrially valuable compounds. We reported the activation of nitriles using mononuclear cobalt(III)–hydroperoxo complexes, [CoIII(Me3-TPADP)(O2H)(RCN)]2+ [R = Me (2) and Ph (2 Ph)], to form cobalt(III)–peroxyimidato complexes, [CoIII(Me3-TPADP)(R–C(NH)O2)]2+ [R = Me (3) and Ph (3 Ph)]. The independence of the rate on the nitrile concentration and the positive Hammett value of 3.2(2) indicated that the reactions occur via an intramolecular nucleophilic attack of the hydroperoxide ligand to the coordinated nitrile carbon atom. In contrast, the previously reported cobalt(III)–hydroperoxo complex, [CoIII(TBDAP)(O2H)(CH3CN)]2+ (2 TBDAP), exhibited the deficiency of reactivity toward nitrile. The comparison of pK a values and redox potentials of 2 and 2 TBDAP showed that Me3-TPADP had a stronger ligand field strength than that of TBDAP. The density functional theory calculations for 2 and 2 TBDAP support that the strengthened ligand field in 2 is mainly due to the replacement of two tert-butyl amine donors in TBDAP with methyl groups in Me3-TPADP, resulting in the compression of the Co–Nax bond lengths. These results provide mechanistic evidence of nitrile activation by the cobalt(III)–hydroperoxo complex and indicate that the basicity dependent on the ligand framework contributes to the ability of nitrile activation.

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Section: Resultssupporting

confidence: 89%

Section: Resultssupporting

confidence: 89%

Mechanistic Insights into Nitrile Activation by Cobalt(III)–Hydroperoxo Intermediates: The Influence of Ligand Basicity

Son,

Jeong,

Kim

et al. 2023

JACS Au

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“…The cobalt(III)–peroxo complexes, [Co III (R 2 -TBDAP)(O 2 )] + ( 3 R2 ; R 2 = Cl, H, and OMe), were synthesized by reacting cobalt(II) complexes, [Co II (R 2 -TBDAP)] 2+ , with H 2 O 2 in the presence of TEA . In the crystal structures, all 3 R2 exhibit octahedral geometries binding the peroxo ligands in a side-on (η 2 ) fashion to the cobalt center (Figure B).…”

Section: Electronic Effect On Cobalt–(hydro)peroxo Complexesmentioning

confidence: 98%

“…10.1021/acs.inorgchem.3c00826Inorg. Chem.20236271417149 Electronic tuning of a pyridinophane ligand was evaluated in properties and reactivities of the cobalt(III)–peroxo and–hydroperoxo intermediates.…”

Section: Key Referencesmentioning

confidence: 99%

“…In contrast to 3 R2 , the cobalt(III)–hydroperoxo complexes, [Co III (R 2 -TBDAP)(O 2 H)(CH 3 CN)] 2+ ( 10 R2 ), exhibited no spin crossover behavior. Instead, a linear trend was observed depending on the electronic nature of substituents . For example, cyclic voltammetry of 10 R2 showed that the redox potentials ( E 1/2 ) increase in the order of 10 OMe (0.19 V) < 10 H (0.24 V) < 10 Cl (0.34 V) (Table ).…”

Section: Electronic Effect On Cobalt–(hydro)peroxo Complexesmentioning

confidence: 99%

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Synthetic Advances for Mechanistic Insights: Metal–Oxygen Intermediates with a Macrocyclic Pyridinophane System

Jeong,

Kim,

Lee

et al. 2023

Acc. Chem. Res.

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Controlling Reactivity through Spin Manipulation: Steric Bulkiness of Peroxocobalt(III) Complexes

Kim,

Lee,

Tripodi

et al. 2024

J. Am. Chem. Soc.

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The intrinsic relationship between spin states and reactivity in peroxocobalt(III) complexes was investigated, specifically focusing on the influence of steric modulation on supporting ligands. Together with the previously reported [Co III (TBDAP)(O 2 )] + (2 Tb ), which exhibits spin crossover characteristics, two peroxocobalt(III) complexes, [Co III (MDAP)-(O 2 )] + (2 Me ) and [Co III (ADDAP)(O 2 )] + (2 Ad ), bearing pyridinophane ligands with distinct N-substituents such as methyl and adamantyl groups, were synthesized and characterized. By manipulating the steric bulkiness of the N-substituents, control of spin states in peroxocobalt(III) complexes was demonstrated through various physicochemical analyses. Notably, 2 Ad oxidized the nitriles to generate hydroximatocobalt(III) complexes, while 2 Me displayed an inability for such oxidation reactions. Furthermore, both 2 Ad and 2 Tb exhibited similarities in spectroscopic and geometric features, demonstrating spin crossover behavior between S = 0 and S = 1. The steric bulkiness of the adamantyl and tertbutyl group on the axial amines was attributed to inducing a weak ligand field on the cobalt(III) center. Thus, 2 Ad and 2 Tb are an S = 1 state under the reaction conditions. In contrast, the less bulky methyl group on the amines of 2 Me resulted in an S = 0 state. The redox potential of the peroxocobalt(III) complexes was also influenced by the ligand field arising from the steric bulkiness of the Nsubstituents in the order of 2 Me (−0.01 V) < 2 Tb (0.29 V) = 2 Ad (0.29 V). Theoretical calculations using DFT supported the experimental observations, providing insights into the electronic structure and emphasizing the importance of the spin state of peroxocobalt(III) complexes in nitrile activation.

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Systematic Electronic Tuning on the Property and Reactivity of Cobalt–(Hydro)peroxo Intermediates

Cited by 3 publications

References 62 publications

Mechanistic Insights into Nitrile Activation by Cobalt(III)–Hydroperoxo Intermediates: The Influence of Ligand Basicity

Mechanistic Insights into Nitrile Activation by Cobalt(III)–Hydroperoxo Intermediates: The Influence of Ligand Basicity

Synthetic Advances for Mechanistic Insights: Metal–Oxygen Intermediates with a Macrocyclic Pyridinophane System

Controlling Reactivity through Spin Manipulation: Steric Bulkiness of Peroxocobalt(III) Complexes

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