Synthesis and Crystal Structure of Manganese(II) Bipyridine Carboxylato Complexes: [(bipy)2MnII(μ-C2H5CO2)2MnII(bipy)2](ClO4)2 and [MnII(ClCH2CO2)(H2O)(bipy)2]ClO4 · H2O (bipy = 2,2′-bipyridine)

Zhang, Cungen; Janiak, Christoph

doi:10.1002/1521-3749(200108)627:8<1972::aid-zaac1972>3.0.co;2-k

Cited by 26 publications

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References 13 publications

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“…They are bridged by two acetato groups in a syn−anti fashion resulting in an intermetal distance of 4.128(1) Å. This is considerably shorter than the distances found in the syn−anti dicarboxylato bridged complexes [Mn 2 (bipy) 4 (μ-C 2 H 5 CO 2 ) 2 ] 2+ (4.653 Å), [Mn 2 (bipy) 4 (μ-C 6 H 5 CO 2 ) 2 ] 2+ (4.509 Å), and [Mn(bipy) 4 (μ-CH 3 O 2 ) 2 ] 2+ (4.583 Å). − Mn−Mn distances similar to that in 1 can be found in two syn−anti diacetato bridged complexes that contain tetradentate nitrogen donor ligands: [Mn 2 (μ-CH 3 CO 2 ) 2 (bispicMe 2 en) 2 ](ClO 4 ) 2 (4.298 Å) (bispicMe 2 en = N , N ‘-dimethyl- N , N ‘-bis(2-pyridylmethyl)ethane-1,2-diamine) and [Mn 2 (μ-CH 3 CO 2 ) 2 (tpa) 2 ](TCNQ) 2 ·2CH 3 CN (4.145 Å) ( tpa = tris(2-pyridylmethyl)amine, TCNQ = tetracyanoquinodimethane). , The coordination environment around the manganese center in 1 is best described as distorted octahedral where four coordination sites are occupied by nitrogen atoms from bpia. It is completed by two oxygen atoms from the bridging acetates.…”

Section: Resultsmentioning

confidence: 87%

Preparation of Highly Efficient Manganese Catalase Mimics

et al. 2002

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The series of compounds [Mn(bpia)(mu-OAc)](2)(ClO(4))(2) (1), [Mn(2)(bpia)(2)(muO)(mu-OAc)](ClO(4))(3).CH(3)CN (2), [Mn(bpia)(mu-O)](2)(ClO(4))(2)(PF(6)).2CH(3)CN (3), [Mn(bpia)(Cl)(2)](ClO)(4) (4), and [(Mn(bpia)(Cl))(2)(mu-O)](ClO(4))(2).2CH(3)CN (5) (bpia = bis(picolyl)(N-methylimidazol-2-yl)amine) represents a structural, spectroscopic, and functional model system for manganese catalases. Compounds 3 and 5 have been synthesized from 2 via bulk electrolysis and ligand exchange, respectively. All complexes have been structurally characterized by X-ray crystallography and by UV-vis and EPR spectroscopies. The different bridging ligands including the rare mono-mu-oxo and mono-mu-oxo-mono-mu-carboxylato motifs lead to a variation of the Mn-Mn separation across the four binuclear compounds of 1.50 A (Mn(2)(II,II) = 4.128 A, Mn(2)(III,III) = 3.5326 and 3.2533 A, Mn(2)(III,IV) = 2.624 A). Complexes 1, 2, and 3 are mimics for the Mn(2)(II,II), the Mn(2)(III,III), and the Mn(2)(III,IV) oxidation states of the native enzyme. UV-vis spectra of these compounds show similarities to those of the corresponding oxidation states of manganese catalase from Thermus thermophilus and Lactobacillus plantarum. Compound 2 exhibits a rare example of a Jahn-Teller compression. While complexes 1 and 3 are efficient catalysts for the disproportionation of hydrogen peroxide and contain an N(4)O(2) donor set, 4 and 5 show no catalase activity. These complexes have an N(4)Cl(2) and N(4)OCl donor set, respectively, and serve as mimics for halide inhibited manganese catalases. Cyclovoltammetric data show that the substitution of oxygen donor atoms with chloride causes a shift of redox potentials to more positive values. To our knowledge, complex 1 is the most efficient binuclear functional manganese catalase mimic exhibiting saturation kinetics to date.

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Section: Resultsmentioning

confidence: 87%

Preparation of Highly Efficient Manganese Catalase Mimics

et al. 2002

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Three‐Component Activation/Alkynylation/Cyclocondensation (AACC) Synthesis of Enhanced Emission Solvatochromic 3‐Ethynylquinoxalines

Merkt

Höwedes

Gers-Panther

et al. 2018

Chemistry A European J

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2-Substituted 3-ethynylquinoxaline chromophores can be readily synthesized by a consecutive activation-alkynylation-cyclocondensation (AACC) one-pot sequence in a three-component manner. In comparison with the previously published four-component glyoxylation starting from electron-rich π-nucleophiles, the direct activation of (hetero)aryl glyoxylic acids allows the introduction of substituents that cannot be directly accessed by glyoxylation. By introducing N,N-dimethylaniline as a strong donor in the 2-position, the emission solvatochromicity of 3-ethynylquinoxalines can be considerably enhanced to cover the spectral range from blue-green to deep red-orange with a single chromophore in a relatively narrow polarity window. The diversity-oriented nature of the synthetic multicomponent reaction concept enables comprehensive investigations of structure-property relationships by Hammett correlations and Lippert-Mataga analysis, as well as the elucidation of the electronic structure of the emission solvatochromic π-conjugated donor-acceptor systems by DFT and time-dependent DFT calculations with the PBEh1PBE functional for a better reproduction of the dominant charge-transfer character of the longest wavelength absorption band.

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From Interwoven to Noninterpenetration: Crystal Structural Motifs of Two New Manganese–Organic Frameworks Mediated by the Substituted Group of the Bridging Ligand

Chen

et al. 2008

Eur J Inorg Chem

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Synthesis and Crystal Structure of Manganese(II) Bipyridine Carboxylato Complexes: [(bipy)2MnII(μ-C2H5CO2)2MnII(bipy)2](ClO4)2 and [MnII(ClCH2CO2)(H2O)(bipy)2]ClO4 · H2O (bipy = 2,2′-bipyridine)

Cited by 26 publications

References 13 publications

Preparation of Highly Efficient Manganese Catalase Mimics

Preparation of Highly Efficient Manganese Catalase Mimics

Three‐Component Activation/Alkynylation/Cyclocondensation (AACC) Synthesis of Enhanced Emission Solvatochromic 3‐Ethynylquinoxalines

From Interwoven to Noninterpenetration: Crystal Structural Motifs of Two New Manganese–Organic Frameworks Mediated by the Substituted Group of the Bridging Ligand

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