Cobalt Corroles with Bis‐Ammonia or Mono‐DMSO Axial Ligands. Electrochemical, Spectroscopic Characterizations and Ligand Binding Properties

Quesneau, Valentin; Shan, Wenqian; Desbois, Nicolas; Brandès, Stéphane; Rousselin, Yoann; Vanotti, Meddy; Blondeau-Pâtissier, Virginie; Naitana, Mario L.; Fleurat‐Lessard, Paul; Caemelbecke, Eric Van; Kadish, Karl M.; Gros, Claude P.

doi:10.1002/ejic.201800897

Cited by 34 publications

(54 citation statements)

References 27 publications

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“…Although the same final [(Ar) 3 CorCo II ] − product is formed in both cases, the difference in thermodynamic half-wave potentials for the one-electron addition can be significant, varying by as much as 1.0 V depending on the type of axial ligand and specific Ar substituents. 38,48,58 One problem with elucidating the effect of axial coordination on the redox potentials of hexacoordinate cobalt corroles is the lability of the axial ligand(s) in solution, which results in a concentration-dependent complexation where one, or both, ligands dissociate in dilute solutions. In search of nonlabile coordinating ligands, we recently investigated the possible binding of anionic ligands to neutral cobalt triarylcorroles and found that 10 of the 11 investigated anionic ligands (PF 6 − , BF 4 − , HSO 4 − , ClO 4 − ,B r − ,I − ,C l − , OAc − ,F − , OTs − ) were unable to bind to the cobalt center of the neutral complex, with the only exception being CN − , where a stepwise formation of both mono-and bis-CN adducts was observed in solutions of CH 2 Cl 2 (eqs 3 and 4).…”

Section: Introductionmentioning

confidence: 99%

Old Dog, New Tricks: Innocent, Five-coordinate Cyanocobalt Corroles

et al. 2020

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Three mono-CN ligated anionic cobalt A 3 -triarylcorroles were synthesized and investigated as to their spectroscopic and electrochemical properties in CH 2 Cl 2 , pyridine (Py), and dimethyl sulfoxide (DMSO). The newly synthesized corroles provide the first examples of air-stable cobalt corroles with an anionic axial ligand and are represented as [(Ar) 3 CorCo III (CN)] − TBA + , where Cor is the trivalent corrole macrocycle, Ar is p-(CN)Ph, p-(CF 3 )Ph, or p-(OMe)Ph, and TBA + is the tetra-n-butylammonium (TBA) cation. Multiple redox reactions are observed for each mono-CN derivative with a key feature being a more facile first oxidation and a more difficult first reduction in all three solvents as compared to all previously examined corroles with similar meso-and β-pyrrole substituents. Formation constants (log K) for conversion of the five-coordinate mono-CN complex to its six-coordinate bis-CN form ranged from 10 2.8 for Ar = p-(OMe)Ph to 10 4.7 for Ar = p-(CN)Ph in DMSO as determined by spectroscopic methodologies. The in situ generated bis-CN complexes, represented as [(Ar)3CorCoIII(CN)2]2−(TBA+)2, and the mixed ligand complexes, represented as [(Ar)3CorCoIII(CN) (Py)]−TBA+, were also investigated as to their electrochemical and spectroscopic properties. UV−visible spectra and electrode reactions of the synthesized mono-CN derivatives are compared with the neutral mono-DMSO cobalt corrole complexes and the in situ generated bis-CN and bis-Py complexes, and the noninnocent (or innocent) nature of each cobalt corrole system is addressed. The data demonstrate the ability of the CN− axial ligand(s) to stabilize the high-valent forms of the metallocorrole, leading to systems with innocent macrocyclic ligands. Although a number of six-coordinate cobalt(III) corroles with N-donor ligands were characterized in the solid state, a dissociation of one axial ligand readily occurs in nonaqueous solvents, and this behavior contrasts with the high stability of the currently studied bis-CN adducts in CH2Cl2, pyridine, or DMSO. Linear free energy relationships were elucidated between the meso-phenyl Hammett substituent constants (Σσ) and the measured binding constants, the redox potentials, and the energy of the band positions in the mono-CN and bis-CN complexes in their neutral or singly oxidized forms, revealing highly predictable trends in the physicochemical properties of the anionic corroles.

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Section: Introductionmentioning

confidence: 99%

Old Dog, New Tricks: Innocent, Five-coordinate Cyanocobalt Corroles

et al. 2020

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“…With the intention to provide the cobalt central atom of complex 1 in a low oxidation state to foster the hydrogenation process, [12a] we conducted the nitrobenzene reduction in the presence of solid reducing agents such as Zn, Mn, and Mg. Rewardingly, the pertinent reaction also proceeded well without external reductants and moreover, the catalytic system did not benefit in any way from the addition of acids or bases (Table S4). If ammonia was added to a solution of 1 in ethanol, formation of the known bis(ammine) cobalt corrole complex was observed [25b] which, however, proved to be inactive in the target transformation. These experimental findings provided compelling reasons that the given Co‐catalyzed nitroarene hydrogenation is best performed without any additives.…”

Section: Resultsmentioning

confidence: 99%

Selective and Additive‐Free Hydrogenation of Nitroarenes Mediated by a DMSO‐Tagged Molecular Cobalt Corrole Catalyst

2021

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We report on the first cobalt corrole that effectively mediates the homogeneous hydrogenation of structurally diverse nitroarenes to afford the corresponding amines. The given catalyst is easily assembled prior to use from 4-tert-butylbenzaldehyde and pyrrole followed by metalation of the resulting corrole macrocycle with cobalt(II) acetate. The thus-prepared complex is self-contained in that the hydrogenation protocol is free from the requirement for adding any auxiliary reagent to elicit the catalytic activity of the applied metal complex. Moreover, a containment system is not required for the assembly of the hydrogenation reaction set-up as both the autoclave and the reaction vessels are readily charged under a regular laboratory atmosphere.

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“…Tetrakis(4-ethynylphenylmethane) 2, 55 corrole 1 59 and metallocorrole 3 37 were prepared according to previously published procedures. Additional information is given in the Supporting Information.…”

Section: Chemicals and Materialsmentioning

confidence: 99%

“…ammonia acting as a protecting group. 37 Interestingly, ammine ligands are sufficiently labile to be easily removed by gentle heating under vacuum to lead to the "active" tetracoordinated cobalt corroles without any bound ligand in apical position. Such square planar complex constitutes the active species of cobalt corroles for CO bonding on the metal center.…”

Section: Synthesis and Characterizationmentioning

confidence: 99%

“…We have very recently addressed this problem and shown that cobalt corroles can be stabilized and easily isolated in air atmosphere without any degradation when the coordination sphere of the metal center is fulfilled with one or two labile axial ligands chosen between DMSO or ammonia, these latter acting as "protecting groups". 37 In addition, the binding properties of CO on metallocorroles is still poorly understood but is relevant with respect to the ubiquity of this gas in polluted air. Permanent porosity and stability are prerequisites for various applications of a material for gas separation or sensing.…”

Section: Introductionmentioning

confidence: 99%

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