Structure of alkali biphenyl ion pairs in solution and in the solid state

Boer, E. de; Klaassen, A. A. K.; Mooij, J. J.; Noordik, J. H.

doi:10.1351/pac197951010073

Cited by 36 publications

(8 citation statements)

References 33 publications

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“…Reactions of an excess of calcium metal (more than 2 equiv) with different substituted (di)halogenobiphenyl derivatives gave deep-green solutions. EPR measurements confirmed the formation of biphenyl dianions in accordance with Rieke’s method of metal activation as well as with studies of alkali-metal−biphenyl adducts …”

Section: Resultssupporting

confidence: 72%

Mechanistic Elucidation of the Formation of the Inverse Ca(I) Sandwich Complex [(thf)₃Ca(μ-C₆H₃-1,3,5-Ph₃)Ca(thf)₃] and Stability of Aryl-Substituted Phenylcalcium Complexes

2010

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The formation of the stable inverse Ca(I) sandwich complex [(thf)(3)Ca(mu-C(6)H(3)-1,3,5-Ph(3))Ca(thf)(3)] (1) has been investigated mechanistically by the reaction of bromo-2,4,6-triphenylbenzene with calcium in varying stoichiometric ratios. The key intermediate consists of a solvent-separated ion pair consisting of a dinuclear calcium cation with a bridging doubly deprotonated triphenylbenzene and a triphenylbenzene radical counteranion [(thf)(3)Ca(mu-C(6)H(2)-C(6)H(4)Ph(2))(mu-O-CH=CH(2))Ca(thf)(3)][C(6)H(3)Ph(3)] (4). A precondition of the formation of 1 is the lability of the heavy Grignard reagent [{2,4,6-Ph(3)C(6)H(2)}Ca(thf)(3)Br] (2), which has been studied along with the role of ether degradation reactions. The strong reducing reagent 1 is stable in THF solution, and ether cleavage does not occur. However, toluene is metalated in good yields, and the dibenzylcalcium complex [(tmta)(2)Ca(CH(2)C(6)H(5))(2)] (5) is generated after addition of 1,3,5-trimethyl-1,3,5-triazinane (tmta). The substitution pattern of arylcalcium halides was modified, and it was found that phenyl substituents at the para position induce lability, leading to an enhanced tendency to cleave ethers. Kinetic stabilization of the Ca-C(ipso) bond can be achieved by ortho substitution using m-terphenyl-based ligands. Direct reaction of iodo-2,6-di(4-tolyl)benzene (6) with activated calcium in THF at low temperatures yielded the first example of a stable m-terphenylcalcium halide, namely, [{2,6-(4-tol)(2)C(6)H(3)}Ca(thf)(3)I] (8). The latter reacts via insertion of carbon dioxide to form the dimeric benzoate [{2,6-(4-tol)(2)C(6)H(3)CO(2)}Ca(thf)(3)I](2) (9).

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Section: Resultssupporting

confidence: 72%

Mechanistic Elucidation of the Formation of the Inverse Ca(I) Sandwich Complex [(thf)₃Ca(μ-C₆H₃-1,3,5-Ph₃)Ca(thf)₃] and Stability of Aryl-Substituted Phenylcalcium Complexes

2010

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“…To achieve delocalization in our system, we postulate that the excited state of [Ru(dpb) 3 ](PF 6 ) 2 is characterized by a ligand conformation in which the 4,4‘-phenyl substituents are coplanar with the bipyridyl fragment. This structural motif is directly analogous to what is observed in biphenyl upon one-electron reduction , and one that is also implicated in the reduced form of paraquat …”

Section: Resultssupporting

confidence: 55%

“…To achieve delocalization in our system, we postulate that the excited state of [Ru(dpb) 3 ](PF 6 ) 2 is characterized by a ligand conformation in which the 4,4′-phenyl substituents are coplanar with the bipyridyl fragment. This structural motif is directly analogous to what is observed in biphenyl upon one-electron reduction 63,64 and one that is also implicated in the reduced form of paraquat. 65 Before leaving this section we wish to point out to the reader that application of the above model (eq 5) to emission spectra results only in a description of vibrational modes that are coupled to radiatiVe transitions from the excited state to the ground state.…”

Section: Aryl-substitutedsupporting

confidence: 61%

Effects of Intraligand Electron Delocalization, Steric Tuning, and Excited-State Vibronic Coupling on the Photophysics of Aryl-Substituted Bipyridyl Complexes of Ru(II)

et al. 1997

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The synthesis and photophysical characterization of a series of aryl-substituted 2,2‘-bipyridyl complexes of RuII are reported. The static and time-resolved emission properties of [Ru(dpb)3](PF6)2, where dpb is 4,4‘-diphenyl-2,2‘-bipyridine, have been examined and are contrasted with those of [Ru(dmb)3](PF6)2 (dmb = 4,4‘-dimethyl-2,2‘-bipyridine). It is shown through analysis of electrochemical data and detailed fitting of the emission spectrum that the unusually large radiative quantum yield for [Ru(dpb)3](PF6)2 in CH3CN solution at room temperature is due to reduction of the degree of geometric distortion along primarily ring-stretch acceptor mode coordinates relative to other molecules in this class. It is proposed that the 3MLCT excited state of [Ru(dpb)3]2+ is characterized by a ligand conformation in which the 4,4‘-phenyl substituents are coplanar with the bipyridyl fragment, leading to extended intraligand electron delocalization and a smaller average change in the C−C bond length upon formation of the excited state as compared to [Ru(dmb)3]2+. These conclusions are further supported by photophysical data on several new molecules, [Ru(dptb)3](PF6)2 (dptb = 4,4‘-di-p-tolyl-2,2‘-bipyridine), [Ru(dotb)3](PF6)2 (dotb = 4,4‘-di-o-tolyl-2,2‘-bipyridine), and [Ru(dmesb)3](PF6)2 (dmesb = 4,4‘-dimesityl-2,2‘-bipyridine). The systematic increase in steric bulk provided by this ligand series results in clear trends in k r, k nr, and S M (the Huang−Rhys factor), consistent with the delocalization model. In addition, time-resolved resonance Raman data reveal frequency shifts in ring-stretch modes across the series supporting the notion that, as the steric bulk of the ligand increases, the ability for the peripheral phenyl rings to become coplanar with the bipyridyl fragment is hindered. Ab initio calculations employing Hartree−Fock and second-order perturbation theory on neutral and anionic 4-phenylpyridine, put forth as a model for the ground and excited states of [Ru(dpb)3]2+, are also reported. These calculations suggest a canted geometry for the ground state, but a considerable thermodynamic driving force for achieving planarity upon reduction of the ligand. The canted ground-state geometry is also observed in the single-crystal X-ray structure of the mixed-ligand complex [Ru(dmb)2(dpb)](PF6)2. Finally, consideration of how this system evolves from the Franck−Condon state to the planar thermalized 3MLCT state is discussed with regard to the possibility of time-resolving the onset of extended electron delocalization in the excited state by using ultrafast spectroscopy.

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“…Smid and Grotens 128 reported the crystalline 1:l complexes of NaBPh 4 with glyme-5, glyme-6 and glyme-7, as well as a 2:l complex with glyme-4. de Boer et al 129 studied the alkali biphenyl (NaBp, KBp and RbBp) in triglyme or tetraglyme solutions by NMR and the crystal structures of NaBp·(2 triglyme), KBp·(2 tetraglyme) and RbBp·(2 tetraglyme) by X-ray diffraction; these crystals consist of solvent-separated ion pairs in the solid state. Magnetic experiments were performed for single crystals of these three systems, and the susceptibility measurements suggested a ferromagnetic coupling in NaBp·(2 triglyme) and KBp·(2 tetraglyme) while an antiferromagnetic coupling in RbBp·(2 tetraglyme).…”

Section: Physicochemical and Metal Complexing Properties Of Glymesmentioning

confidence: 99%

Glymes as versatile solvents for chemical reactions and processes: from the laboratory to industry

2014

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Glymes, also known as glycol diethers, are saturated non-cyclic polyethers containing no other functional groups. Most glymes are usually less volatile and less toxic than common laboratory organic solvents; in this context, they are more environmentally benign solvents. However, it is also important to point out that some glymes could cause long-term reproductive and developmental damages despite their low acute toxicities. Glymes have both hydrophilic and hydrophobic characters that common organic solvents are lack of. In addition, they are usually thermally and chemically stable, and can even form complexes with ions. Therefore, glymes are found in a broad range of laboratory applications including organic synthesis, electrochemistry, biocatalysis, materials, and Chemical Vapor Deposition (CVD), etc. In addition, glyme are used in numerous industrial applications, such as cleaning products, inks, adhesives and coatings, batteries and electronics, absorption refrigeration and heat pumps, as well as pharmaceutical formulations, etc. However, there is a lack of comprehensive and critical review on this attractive subject. This review aims to accomplish this task by providing an in-depth understanding of glymes’ physicochemical properties, toxicity and major applications.

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Structure of alkali biphenyl ion pairs in solution and in the solid state

Cited by 36 publications

References 33 publications

Mechanistic Elucidation of the Formation of the Inverse Ca(I) Sandwich Complex [(thf)₃Ca(μ-C₆H₃-1,3,5-Ph₃)Ca(thf)₃] and Stability of Aryl-Substituted Phenylcalcium Complexes

Mechanistic Elucidation of the Formation of the Inverse Ca(I) Sandwich Complex [(thf)₃Ca(μ-C₆H₃-1,3,5-Ph₃)Ca(thf)₃] and Stability of Aryl-Substituted Phenylcalcium Complexes

Effects of Intraligand Electron Delocalization, Steric Tuning, and Excited-State Vibronic Coupling on the Photophysics of Aryl-Substituted Bipyridyl Complexes of Ru(II)

Glymes as versatile solvents for chemical reactions and processes: from the laboratory to industry

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Structure of alkali biphenyl ion pairs in solution and in the solid state

Cited by 36 publications

References 33 publications

Mechanistic Elucidation of the Formation of the Inverse Ca(I) Sandwich Complex [(thf)3Ca(μ-C6H3-1,3,5-Ph3)Ca(thf)3] and Stability of Aryl-Substituted Phenylcalcium Complexes

Mechanistic Elucidation of the Formation of the Inverse Ca(I) Sandwich Complex [(thf)3Ca(μ-C6H3-1,3,5-Ph3)Ca(thf)3] and Stability of Aryl-Substituted Phenylcalcium Complexes

Effects of Intraligand Electron Delocalization, Steric Tuning, and Excited-State Vibronic Coupling on the Photophysics of Aryl-Substituted Bipyridyl Complexes of Ru(II)

Glymes as versatile solvents for chemical reactions and processes: from the laboratory to industry

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Mechanistic Elucidation of the Formation of the Inverse Ca(I) Sandwich Complex [(thf)₃Ca(μ-C₆H₃-1,3,5-Ph₃)Ca(thf)₃] and Stability of Aryl-Substituted Phenylcalcium Complexes

Mechanistic Elucidation of the Formation of the Inverse Ca(I) Sandwich Complex [(thf)₃Ca(μ-C₆H₃-1,3,5-Ph₃)Ca(thf)₃] and Stability of Aryl-Substituted Phenylcalcium Complexes