Hybrid Molecular Systems Containing Tetrathiafulvalene and Iron‐Alkynyl Electrophores: Five‐Component Functional Molecules Obtained from CH Bond Activation

Justaud, Frédéric; Gendron, Frédéric; Ogyu, Yoshiyuki; Kumamoto, Yuki; Miyazaki, Akira; Ouahab, Lahcène; Costuas, Karine; Halet, Jean‐François; Lapinte, Claude

doi:10.1002/chem.201204227

Cited by 11 publications

(11 citation statements)

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“…Pertinent geometrical data are given in Table S1. The optimized distances for the neutral system are similar to those computed for the related compound 10 , and the metal–ligand distances are characteristic of Fe II centers in pseudooctahedral environments 26. Upon oxidation, the metal–ligand (dppe, Cp*) bonds are lengthened.…”

Section: Resultssupporting

confidence: 57%

“…It is useful to note that the use of t BuOK as a reducing agent has not been frequently reported. Indeed, it behaves as an efficient reducing reagent and is much cheaper and more convenient to use than cobaltocene, for instance 26,36. The redox potentials indicate that the reduction is not under thermodynamic control.…”

Section: Resultsmentioning

confidence: 99%

“…Finally, the synthesis and characterization of the three multicomponent molecular assemblies [Cp*(dppe)Fe=C=C=TTFMe 2 =CH–CH=TTFMe 2 =C=C=Fe(dppe)Cp*][PF 6 ] n ( 10 [PF 6 ] n , n = 0, 1, 2) has been reported 26. The experimental data were analyzed with the support of a theoretical study performed at the DFT level on the full structures.…”

Section: Introductionmentioning

confidence: 99%

“…With five components, namely, the two Fe centers, the two TTFMe 2 moieties, and the connecting organic bridge, the mixed‐valence 10 [PF 6 ] strongly differs from related mixed‐valence metal–organic bridge–metal systems and, to the best of our knowledge, is unprecedented. The involvement of all these components in the electron‐transfer process renders the usual Hush–Marcus two‐center model inappropriate 26,27…”

Section: Introductionmentioning

confidence: 99%

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Synthesis and Properties of a Mixed‐Valence Compound with Single‐Step Tunneling and Multiple‐Step Hopping Behavior

et al. 2014

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The organic precursor bis(trimethylsilylethynyl)TTFMe2 (3, TTF = tetrathiafulvalene) was prepared as a 1:1 mixture of the cis and trans isomers. Pure samples of 3‐cis and 3‐trans were obtained by crystallization and identified by XRD analysis. The treatment of pure 3‐trans and a 1:1 mixture of 3‐cis/trans with (i) potassium carbonate, (ii) the iron complex Cp*(dppe)FeCl [5, Cp* = η5‐C5Me5, dppe = 1,2‐bis(diphenylphosphanyl)ethane] in the presence of KPF6, and (iii) tBuOK provided Cp*(dppe)Fe–C≡C–TTFMe2–C≡C–Fe(dppe)Cp* as the pure geometric isomer 6‐trans (85 %) and as the 60:40 mixture 6‐cis/trans (63 %), respectively. The oxidation of 6‐trans with [(C5H5)2Fe]PF6 gave [6‐trans][PF6]n (n = 1–3). Visible, IR, near‐IR (NIR), and electron paramagnetic resonance (EPR) spectroscopy together with DFT data show that [6‐trans][PF6] is a class II mixed‐valence complex (Hab = 85 cm–1) in which the spin distribution depends on the conformation of the molecule. Intramolecular electron transfer occurs through single‐step tunneling and a multistep hoping mechanism. The triplet state is thermally accessible for [6‐trans][PF6]2.

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Section: Resultssupporting

confidence: 57%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Synthesis and Properties of a Mixed‐Valence Compound with Single‐Step Tunneling and Multiple‐Step Hopping Behavior

et al. 2014

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“…[1][2][3][4] Recently, numerous organic conjugative ligands and redox-active metal terminals were used to develop a type of "organometallic molecular wires" model. [9] As for the metal terminal groups, iron, [10] ruthenium, [7,8,11] osmium, [12] and molybdenum [13] units with different auxiliary ligands, such as cyclopentadienyl, bis(diphenylphosphino)ethane (dppe) are typically used because of their redox-active properties and electrochemical stability. [9] As for the metal terminal groups, iron, [10] ruthenium, [7,8,11] osmium, [12] and molybdenum [13] units with different auxiliary ligands, such as cyclopentadienyl, bis(diphenylphosphino)ethane (dppe) are typically used because of their redox-active properties and electrochemical stability.…”

Section: Introductionmentioning

confidence: 99%

Binuclear Ruthenium Complexes with Benzo[1,2‐b;4,5‐b′]dithiophene Analogues as Bridge Ligands: Syntheses, Characterization and Notable Difference on Electronic Coupling

Tang

Wang

et al. 2017

Chin. J. Chem.

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Diruthenium ethynyl complexes 1-3 (1: 1,5-dithia-s-indacene-4,8-dione; 2: 4,8-diethoxybenzo [1,2-b:4,5b']dithiophene; 3: 4,8-didodecyloxybenzo[1,2-b:4,5-b']dithiophene) have been synthesized by incorporating the respective conjugated heterocyclic spacer and characterized by NMR and elemental analysis. The effects of bridge ligands' properties on electronic coupling between redox-active ruthenium terminal groups were investigated by electrochemistry, UV/vis/near-IR and IR spectroelectrochemistry combined with density functional theory (DFT) and time-dependent DFT calculations. Electrochemistry results indicated that complexes 1-3 exhibit two fully reversible oxidation waves, and complexes 2 and 3 with electron-rich and π-conjuagted bridge ligands are characterized by excellent electrochemical properties. Furthermore, the larger ν(C≡C) separation from the IR spectroelectrochemical results of 2 and 3 and the intense NIR absorption features of singly oxidized species 2 ＋ and 3 ＋ revealed that their molecular skeletons have superior abilities to delocalize the positive charge. The spin density distribution from DFT calculations proved the conclusions of this study.

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Electronic Properties of Poly‐Yne Carbon Chains and Derivatives with Transition Metal End‐Groups

et al. 2020

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During the last three decades, experimental chemists have forged a plethora of bimetallic molecular wires in which two redox‐active metal termini are linked by a carbon‐rich bridge. Their extensive redox chemistry with multiple, stepwise, one‐electron oxidation processes provide them with some interesting electronic and/or magnetic properties for potential applications. The nature of both the metal end‐groups and the carbon bridge has a significant effect on the redox process, which is of paramount importance for the design of these systems. Indeed, examples of mono‐oxidized complexes range from weakly coupled mixed‐valence species through more strongly coupled systems in which the bridging ligand can be intimately involved in electron transfer processes. Similarly, di‐oxidized species can encompass difference in magnetic behavior depending upon not only the nature of the framework of the systems but also the torsion angle between the terminal spin carriers, which allows the inversion of the singlet vs. triplet ground states. Theoretical quantum chemical computations have greatly assisted the development of this field of research. This review illustrates how, in synergy with experiments, computational results can provide additional valuable information on the nature of the localized vs. delocalized electronic communication in the mono‐oxidized mixed‐valence species, or the magnetic coupling differences and characteristics of the di‐oxidized complexes.

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Hybrid Molecular Systems Containing Tetrathiafulvalene and Iron‐Alkynyl Electrophores: Five‐Component Functional Molecules Obtained from CH Bond Activation

Cited by 11 publications

References 109 publications

Synthesis and Properties of a Mixed‐Valence Compound with Single‐Step Tunneling and Multiple‐Step Hopping Behavior

Synthesis and Properties of a Mixed‐Valence Compound with Single‐Step Tunneling and Multiple‐Step Hopping Behavior

Binuclear Ruthenium Complexes with Benzo[1,2‐b;4,5‐b′]dithiophene Analogues as Bridge Ligands: Syntheses, Characterization and Notable Difference on Electronic Coupling

Electronic Properties of Poly‐Yne Carbon Chains and Derivatives with Transition Metal End‐Groups

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