Structures of mixed manganese ruthenium oxides (Mn1−xRux)O2(Mn_{1−x}Ru_x)O_2 crystallised under acidic hydrothermal conditions

A synthesis method for the preparation of mixed manganese–ruthenium oxides is presented along with a detailed characterisation of the solids produced. The use of 1 M aqueous sulfuric acid mediates the redox reaction between KRuO$_4$, KMnO$_4$ and Mn$^{2+}$ to form ternary oxides. At reaction temperature of 100°C the products are mixtures of α-MnO$_2$ (hollandite-type) and β-MnO$_2$ (rutile-type), with some evidence of Ru incorporation in each from their expanded unit cell volumes. At reaction temperature of 200°C solid-solutions β-Mn$_{1−x}$Ru$_x$O$_2$ are formed and materials with x ≤ 0.6 have been studied. The amount of Ru included in the oxide is greater than expected from the ratio of metals used in the synthesis, as determined by elemental analysis, implying that some Mn remains unreacted in solution. Powder X-ray diffraction (XRD) shows that while the unit cell volume expands in a linear manner, following Vegard's law, the tetragonal lattice parameters, and the a/c ratio, do not follow the extrapolated trends: this anisotropic behaviour is consistent with the different local coordination of the metals in the end members. Powder XRD patterns show increased peak broadening with increasing ruthenium content, which is corroborated by electron microscopy that shows nanocrystalline material. X-ray absorption near-edge spectra show that the average oxidation state of Mn in the solid solutions is reduced below +4 while that of Ru is increased above +4, suggesting some redistribution of charge. Analysis of the extended X-ray absorption fine structure provides complementary local structural information, confirming the formation of a solid solution, while X-ray photoelectron spectroscopy shows that the surface oxidation states of both Ru and Mn are on average lower than +4, suggesting a disordered surface layer may be present in the materials

One- and two-electron reduced 1,2-diketone ligands in [CrIII(L•)3] (S = 0) and Na2(Et2O)2[VIV(LRed)3] (S = 1/2)

The 1,2-diketone bis(2,6-diisopropylphenyl)glyoxal (LOx)0 is demonstrated to be a versatile, redox active ligand with the isolation of two early transition metal complexes, namely, octahedral [CrIII(L•)3]0 (1) (S = 0) and trigonal prismatic Na2(Et2O)2[VIV(LRed)3] (2) (S = 1/2). Structural, spectroscopic, and density functional theory (DFT) studies of these complexes, combined with a DFT investigation of the products of one- and two-electron oxidation of 2, provide insight into the factors that combine to enforce an octahedral or trigonal prismatic geometry

Characterisation of platinum-based fuel cell catalyst materials using 195Pt wideline solid state NMR

This study demonstrates the utility of the novel Field Sweep Fourier Transform (FSFT) method for acquiring wideline 195Pt NMR data from various sized Pt nanoparticles, Pt–Sn intermetallics/bimetallics used to catalyse oxidative processes in fuel cell applications, and various other related Pt3X alloys (X = Al, Sc, Nb, Ti, Hf and Zr) which can facilitate oxygen reduction catalysis. The 195Pt and 119Sn NMR lineshapes measured from the PtSn intermetallic and Pt3Sn bimetallic systems suggest that these are more ordered than other closely related bimetallic alloys; this observation is supported by other characterisation techniques such as XRD. From these reconstructed spectra the mean number of atoms in a Pt nanoparticle can be accurately determined, along with detailed information regarding the number of atoms present effectively in each layer from the surface. This can be compared with theoretical predictions of the number of Pt atoms in these various layers for cubo-octahedral nanoparticles, thereby providing an estimate of the particle size. A comparison of the common NMR techniques used to acquire wideline data from the I = 1/2 195Pt nucleus illustrates the advantages of the automated FSFT technique over the Spin Echo Height Spectroscopy (SEHS) (or Spin Echo Integration Spectroscopy (SEIS)) approach that dominates the literature in this area of study. This work also presents the first 195Pt NMR characterisation of novel small Pt13 nanoclusters which are diamagnetic and thus devoid of metallic character. This unique system provides a direct measure of an isotropic chemical shift for these Pt nanoparticles and affords a better basis for determining the actual Knight shift when compared to referencing against the primary IUPAC shift standard (1.2 M Na2PtCl6(aq)) which has a very different local chemical environment