Chiral Cobalt‐Salen Complexes: Ubiquitous Species in Asymmetric Catalysis

Schulz, Emmanuelle

doi:10.1002/tcr.202000166

Cited by 12 publications

(7 citation statements)

References 93 publications

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“…Cobalt complexes gained renewed interest due to their diverse functional properties in metalloenzymes, [1][2][3][4] as single-molecule magnets, [5][6][7][8][9][10][11][12][13][14][15][16] in catalysis, [17][18][19][20][21] water oxidation, [22][23][24][25][26][27] proton reduction, [22,[28][29][30][31][32][33][34][35][36][37][38] carbon dioxide reduction, [28,[39][40][41][42][43][44] and cytotoxicity. [45] In order to mimic dinuclear metalloenzymes active sites and consequently to obtain new dinuclear catalysts we have recently developed a dinucleating ligand system comprised of two tetradentate tripodally coordinating ligand compartments with varying terminal donors that are bridged by an ethylene spacer.…”

Section: Introductionmentioning

confidence: 99%

Molecular and Electronic Structures of a Series of Dinuclear Co^II Complexes Varied by Exogeneous Ligands: Influence of π‐Bonding on Redox Potentials

et al. 2022

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Four dinuclear Co II complexes have been synthesized and structurally characterized with the dinucleating ligand susan (susan = 4,7-dimethyl-1,1,10,10-tetra(2-pyridylmethyl)-1,4,7,10tetraazadecane) varying in the exogeneous ligands:-{Co II Br} 2 ](ClO 4 ) 2 , and [(susan){Co II (μ-OH)Co II }](ClO 4 ) 3 . The Co II ions are six-coordinate with CH 3 CN ligands and five-coordinate with anionic ligands. The electronic absorption spectra reflect the differences in the electronic structures, not only between the six-and five-coordinate complexes, but also between the fivecoordinate complexes. These variations are also reflected in the magnetic properties with the highest orbital angular momen-tum contribution in six-coordinate [(susan){Co II (CH 3 CN) 2 } 2 ](PF 6 ) 4 . The lower symmetry in the five-coordinate complexes reduces the orbital angular momentum contribution. The hydroxobridged complex [(susan){Co II (μ-OH)Co II }](ClO 4 ) 3 exhibits an additional antiferromagnetic interaction. The electrochemical characterization reveals that the π-acceptor ligand CH 3 CN facilitates not only reduction from Co II to Co I but also oxidation to Co III , while the π-donor ligands Br À , Cl À , and μ-OH À impede both reduction to Co I and oxidation to Co III . [(susan){Co II -(CH 3 CN) 2 } 2 ](PF 6 ) 4 and [(susan){Co II Cl} 2 ](ClO 4 ) 2 show electrocatalytic proton reduction at a potential of � À 1.9 V vs Fc + /Fc that is associated with a ligand-centered reduction.

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Section: Introductionmentioning

confidence: 99%

Molecular and Electronic Structures of a Series of Dinuclear Co^II Complexes Varied by Exogeneous Ligands: Influence of π‐Bonding on Redox Potentials

et al. 2022

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“…[23][24][25] Schiff bases, characterized by an imine (4CQN-) or an azomethine (-CHQN-) group, 26,27 form an outstanding class of proligands that play a key role in the development of coordination chemistry due to their facile synthesis, structural flexibility, easily tunable electronic properties, selectivity and sensitivity towards the coordinated metal ion and their ability to form stable complexes under various coordination geometries and oxidation states. 22,[28][29][30] Transition-metal complexes of Schiff base ligands have been widely investigated because of their applications in various branches of science such as in catalysis, [31][32][33] sensing, [34][35][36] as NLO molecular materials, 23,[37][38][39] and in biochemistry, [40][41][42] among others. Ferrocene substituted asymmetric N 2 O 2 -tetradentate Schiff bases are generally obtained upon condensation of salicylaldehyde or its derivatives with a preformed tridentate organometallic precursor bearing a free amino group.…”

Section: Introductionmentioning

confidence: 99%

Ferrocene functionalized enantiomerically pure Schiff bases and their Zn(ii) and Pd(ii) complexes: a spectroscopic, crystallographic, electrochemical and computational investigation

et al. 2022

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“…In the past few decades, catalytic hydration of epoxides has been investigated to obtain environmentally friendly glycol at a low energy cost, and various types of catalysts, such as ionic liquids, ,, zeolites, − and metal–salen catalysts, − have been explored. Metal–salen complexes are versatile and have been proven to be effective catalysts for epoxide hydration, apart from asymmetric ring-opening reactions, CO 2 cycloaddition/copolymerization with epoxides, and asymmetric alkene epoxidation/Diels–Alder reactions. − …”

Section: Introductionmentioning

confidence: 99%

Theoretical Studies on Bimetallic Salen Complexes Catalyzed Epoxide Hydration: Effects of Metal Centers, Substrates, and Ligands

Yang

Chen

2021

J. Phys. Chem. A

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To provide guiding information for developing efficient and stable catalysts for epoxide hydration, we investigated the mechanism of propylene oxide (PO) to 1,2-propylene glycol (PG) using density functional theory (DFT) calculations. The mechanism was identified to follow the cooperative bimetallic mechanism in which a metal–salen complex activated H2O attacks the middle carbon atom of a metal–salen complex activated PO from the oxygen side of three-membered ring. Analyses reveal that the distortion energy correlates linearly with the barrier, and the hydrogen bonding between H2O and PO increases from reaction precursors to transition states. A nice linear relationship exists between the ratio of square root of ionic potential to the square of the distance from the metal ion spherical surface to the oxygen atom center of PO. It is demonstrated that the substrates with larger polarizability tend to have lower hydration barriers and the influence of ligands is less than that of metal centers and substrates. Modifying metal ions is the first choice for developing metal–salen catalysts, and metal ions with more formal charges and larger radius are expected to exhibit high activity. These findings shed lights on the mechanism and provide guiding information for developing efficient metal–salen catalysts for epoxide hydration.

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Chiral Cobalt‐Salen Complexes: Ubiquitous Species in Asymmetric Catalysis

Cited by 12 publications

References 93 publications

Molecular and Electronic Structures of a Series of Dinuclear Co^II Complexes Varied by Exogeneous Ligands: Influence of π‐Bonding on Redox Potentials

Molecular and Electronic Structures of a Series of Dinuclear Co^II Complexes Varied by Exogeneous Ligands: Influence of π‐Bonding on Redox Potentials

Ferrocene functionalized enantiomerically pure Schiff bases and their Zn(ii) and Pd(ii) complexes: a spectroscopic, crystallographic, electrochemical and computational investigation

Theoretical Studies on Bimetallic Salen Complexes Catalyzed Epoxide Hydration: Effects of Metal Centers, Substrates, and Ligands

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Chiral Cobalt‐Salen Complexes: Ubiquitous Species in Asymmetric Catalysis

Cited by 12 publications

References 93 publications

Molecular and Electronic Structures of a Series of Dinuclear CoII Complexes Varied by Exogeneous Ligands: Influence of π‐Bonding on Redox Potentials

Molecular and Electronic Structures of a Series of Dinuclear CoII Complexes Varied by Exogeneous Ligands: Influence of π‐Bonding on Redox Potentials

Ferrocene functionalized enantiomerically pure Schiff bases and their Zn(ii) and Pd(ii) complexes: a spectroscopic, crystallographic, electrochemical and computational investigation

Theoretical Studies on Bimetallic Salen Complexes Catalyzed Epoxide Hydration: Effects of Metal Centers, Substrates, and Ligands

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Molecular and Electronic Structures of a Series of Dinuclear Co^II Complexes Varied by Exogeneous Ligands: Influence of π‐Bonding on Redox Potentials

Molecular and Electronic Structures of a Series of Dinuclear Co^II Complexes Varied by Exogeneous Ligands: Influence of π‐Bonding on Redox Potentials