Incommensurability induced by intermolecular hydrogen bonding

Non-symmetric dimesogens are composed of two different mesogenic units linked via a flexible spacer. In this study, a new type of non-symmetric dimesogen has been built through the self-assembly via intermolecular hydrogen bonding between appropriately designed H-bond donor (3-cholesteryloxycarbonylpentanoic acid) and acceptor (aromatic mesogen with a pyridyl group) moieties. As for covalently linked dimesogens, several types of smectic periodicities are observed for these H-bonded cholesteryl compounds depending on the length of the terminal chain of the acceptor moiety: a smectic periodicity resulting from associated dimesogens is observed for long terminal chains, while short chain homologues display an intercalated structure corresponding to half the molecular length. The competition between these two incommensurate lengths can induce an incommensurate smectic phase where the two smectic periodicities coexist at long range.     

Unexpected shielding of methyl group protons in some piperidines

High resolution 1H and 13C NMR spectra of four 3-ethyl-4-hydroxy- 4-phenylpiperidines 1-4 have been recorded in CDCl3 and analysed. The conformations of phenyl and hydroxyl groups at C(4) and ethyl group at C(3) were analysed in detail. The chemical shift of the methyl protons in the ethyl group are quite surprising; they are close to TMS in CDCl(3) and even negative in DMSO-d6. These results are interpreted in terms of the magnetic anisotropy of the phenyl rings at C(2) and C(4) which, in turn, depend on the conformations of the ethyl group at C(3) and the hydroxyl group at C(4). Favoured conformations of ethyl group at C(3) and hydroxyl group at C(4) were calculated by AM1 methods.     

Micro‐Raman investigations on inclusions of unusual habit in a commercial tanzanite gemstone

The vibrational properties of submillimetre size inclusions of unusual habit in a commercial tanzanite gemstone were investigated by confocal Raman microspectroscopy with the aim of probing both their chemical composition and crystal structure. Highly contrasted Raman spectra were recorded in confocal conditions from several inclusions incorporated at different depths, ranging between a few microns to some tens of microns beneath the gemstone surface. The observed spectral features were identified as specific markers of hematite (α‐Fe₂O₃). Their unambiguous assignment has been inferred by comparing our experimental findings with the literature data recorded either in single crystals of hematite or in other iron oxides and oxyhydroxides. Our results rule out the presence of any pseudomorphic variety of hematite in the investigated gemstone, while confocal micro‐Raman spectroscopy definitively proved itself as a very reliable, relatively costless and noninvasive tool for unambiguous identification of subsurface regions of gemstones. Copyright © 2011 John Wiley & Sons, Ltd.     

Carbon Monoxide Coupling Reactions: A New Concept for the Formation of Hexahydroxybenzene

For linear and cyclic coupling reactions of CO, among other products, the formation of the hexapotassium salt of hexahydroxybenzene is of particular interesting. The interaction of metallic potassium and CO offers, via the assumed K[OC≡CO]K as the result of several carbon monoxide coupling reactions, the formation of C₆(OK)₆ among other products. To date, only speculations exist about the reaction pathway for these products, which were first described by Liebig in 1834. A novel concept is suggested here, which consists of the single steps (i) reductive coupling of CO, (ii) formation of dihetero-metallacyclopentynes (cis-2,5-diheterobutatriene as formal ethylenedione O=C=C=O complexes), (iii) formation of its dinuclear 1-metalla-2,5-dioxo-cyclopentyne complexes by external coordination of the triple bond, (iv) insertion of CO into the M−C bond of the formed metallacyclopropene, and (v) the reductive elimination of C₆(OK)₆. The novel aspect of this concept is the formation of dihetero-metallacyclopentynes (in analogy to the well characterized all-C-metallacyclopentynes), which have not been considered in the mechanism of reductive CO coupling reactions. It is expected that the presence of transition-metal impurities would promote the reaction.