Interfacial roughness in multilayer films may be random or correlated, i.e., replicated from layer to layer. It is shown that these can be separated and quantified using x-ray diffraction rocking curves and a straightforward analysis. The lateral correlation length along the interfaces can additionally be determined. A quantitative evaluation for W/C multilayers shows that correlated roughness contributes significantly to the total roughness, even at length scales that are surprisingly short, of the order 2–6 nm.
The presence of carbonates in inclusions in diamonds coming from depths exceeding 670 km are obvious evidence that carbonates exist in the Earth’s lower mantle. However, their range of stability, crystal structures and the thermodynamic conditions of the decarbonation processes remain poorly constrained. Here we investigate the behaviour of pure iron carbonate at pressures over 100 GPa and temperatures over 2,500 K using single-crystal X-ray diffraction and Mössbauer spectroscopy in laser-heated diamond anvil cells. On heating to temperatures of the Earth’s geotherm at pressures to ∼50 GPa FeCO3 partially dissociates to form various iron oxides. At higher pressures FeCO3 forms two new structures—tetrairon(III) orthocarbonate Fe43+C3O12, and diiron(II) diiron(III) tetracarbonate Fe22+Fe23+C4O13, both phases containing CO4 tetrahedra. Fe4C4O13 is stable at conditions along the entire geotherm to depths of at least 2,500 km, thus demonstrating that self-oxidation-reduction reactions can preserve carbonates in the Earth’s lower mantle.
The UV-vis electronic absorption and fluorescence emission properties of 8-halogenated (Cl, Br, I) difluoroboron dipyrrin (or 8-haloBODIPY) dyes and their 8-(C, N, O, S) substituted analogues are reported. The nature of the meso-substituent has a significant influence on the spectral band positions, the fluorescence quantum yields, and lifetimes. As a function of the solvent, the spectral maxima of all the investigated dyes are located within a limited wavelength range. The spectra of 8-haloBODIPYs display the narrow absorption and fluorescence emission bands and the generally quite small Stokes shifts characteristic of classic difluoroboron dipyrrins. Conversely, fluorophores with 8-phenylamino (7), 8-benzylamino (8), 8-methoxy (9), and 8-phenoxy (10) groups emit in the blue range of the visible spectrum and generally have larger Stokes shifts than common BODIPYs, whereas 8-(2-phenylethynyl)BODIPY (6) has red-shifted spectra compared to ordinary BODIPY dyes. Fluorescence lifetimes for 6, 8, and 10 have been measured for a large set of solvents and the solvent effect on their absorption and emission maxima has been analyzed using the generalized Catalán solvent scales. Restricted rotation about the C8-N bond in 7 and 8 has been observed via temperature dependent (1)H NMR spectroscopy, whereas for 10 the rotation about the C8-O bond is not hindered. The crystal structure of 8 demonstrates that the short C8-N bond has a significant double character and that this N atom exhibits a trigonal planar geometry. The crystal structure of 10 shows a short C8-O bond and an intramolecular C-H···π interaction. Quantum-chemical calculations have been performed to assess the effect of the meso-substituent on the spectroscopic properties.
Gold-catalyzed carbocyclization and heteroannulation strategies have recently attracted much attention owing to the selective and efficient activation of the CC bond towards a wide range of nucleophiles that these methods provide.[1] Domino approaches involving gold-catalysis lead to complex heterocyclic compounds under exceedingly mild reaction conditions.[2] Although gold-catalyzed approaches are rising to prominence, they suffer in terms of diversity and procedural length. Multistep sequences are usually required for assembling the starting material for cyclization. We have recently reported a concise route to indoloazocines by a sequential Ugi/gold-catalyzed intramolecular hydroarylation approach.[3] Inspired by these findings and as a result of our continued synthetic interest in the indole core, [4] multicomponent reactions [5] and transition metal-catalysis, [6] we have developed a post-Ugi gold-catalyzed domino cyclization method to generate spiroindolines.The Ugi four-component reaction (4-CR) [7] of indole-3-carboxaldehyde (1 a) with p-methoxybenzyl amine (2 a), 2-butynoic acid (3 a) and tert-butyl isonitrile (4 a) in methanol at 50 8C gave Ugi-adduct 5 a in 71 % yield. When this was treated with 5 mol % of Au[PPh 3 ]OTf (OTf = trifluoromethanesulfonate) in CDCl 3 at RT, the expected outcome of the reaction was indoloazepinone 6 a' through an endo-dig cyclization [1m,n, 3] followed by rearrangement (Scheme 1). Surprisingly, an exo-dig cyclization followed by intramolecular trapping of the spiro intermediate occurred instead, resulting in the diastereoselective formation of tetracyclic spiroindoline 6 a in 61 % yield (Scheme 1).This observation was remarkable, as the attack on the a-position of an alkyne conjugated with an amide is rare, and trapping of the spiro intermediate by a sterically hindered tert-butyl amide is rather unexpected, as was the diastereoselectivity observed. Spiroindolines [8] are prominent molecular motifs that are frequently encountered among the large family of alkaloids; for example, it is present in communesines [8,9] and perophoramidines [8,10] (Figure 1), which display distinct pharmacological properties. [8][9][10] These fused polycyclic systems, which feature quaternary stereocenters, present a nontrivial challenge for organic chemists to develop synthetic approaches.
The ionic liquid choline bis(trifluoromethylsulfonyl)imide, [Chol][Tf2N], was used for the extraction of neodymium(III), in combination with choline hexafluoroacetylacetonate, [Chol][hfac], as the extractant. The binary mixture of [Chol][Tf2N] and water shows temperature-dependent phase behavior, with an upper critical solution temperature of 72 °C. A novel extraction technique, homogeneous liquid-liquid extraction (HLLE), was applied to this solvent system. HLLE is based on the use of thermomorphic solvent mixtures and has the advantage of forming a homogeneous phase during mixing. Extraction is not kinetically hindered by an interface and the extraction equilibrium is reached faster than in the case of heterogeneous mixing in conventional solvent extraction. Several extraction parameters were studied for the extraction of neodymium(III) with [Chol][hfac]: temperature, pH, extractant concentration and loading of the ionic liquid phase. A speciation study was performed to determine the stoichiometry of the extracted neodymium(III) complex and a plausible extraction mechanism is proposed. Neodymium is extracted as a tetrakis hexafluoroacetylacetonate complex with one choline cation as counter ion. The crystal structure of the extracted complex showed the presence of a coordination bond between the choline counter ion and the neodymium(III) center, resulting in a coordination number of nine. The stripping of the loaded neodymium and the influence of acid and extractant concentrations on the phase behavior of the [Chol][Tf2N]-H2O system were investigated.
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