Due to their ease of fabrication and monodisperse, metallic nature, molybdenum-sulfur-iodine nanowires are an interesting alternative to carbon nanotubes for some applications. However very little is known about the solubility of these materials. In this work we have investigated the solubility of Mo(6)S(4.5)I(4.5) nanowire soot in a range of common solvents by performing sedimentation studies and microscopic and spectroscopic characterization. A sedimentation equation was derived showing that the concentration of any insoluble dispersed phase decreases exponentially with time. We find that in all solvents, Mo(6)S(4.5)I(4.5) nanowire soot contains three phases, two of which are insoluble with one stable phase. Microscopy and spectroscopy show that the first insoluble phase is associated mainly with spherical impurities and sediments rapidly out of solution resulting in purification. The second phase appears to consist of insoluble nanowire bundles and sediments more slowly, eventually leaving a stable dispersion of nanowire bundles. The stably dispersed bundles tend to be smaller than their insoluble counterparts. The best solvents studied were 2-propanol and dimethylformamide. Microscopy studies showed that, in the case of 2-propanol, sonication significantly reduced the bundle size relative to the unsonicated bulk. However, during sedimentation, large quantities of bundles were observed to reaggregate to form larger bundles which subsequently sedimented out of solution. In general, the sedimentation properties of the various phases did not vary significantly with concentration indicating that the insoluble nanowires are intrinsically insoluble. However, the diameter of the stably dispersed bundles decreased with concentration, until very small bundles consisting of only two or three nanowires were observed at concentrations below 0.003 mg/mL. In addition, stable composite dispersions were produced by mixing the nanowires with poly(vinylpyrrolidone) in 2-propanol opening the way for the formation of polymer/inorganic nanowire composites.
We report on the properties of a new air-stable nanowire material with the chemical formula
Mo6S3I6. The distinguishing features of the material are rapid one-step synthesis, easy isolation and
controllable dispersion into small-diameter wire bundles. Elemental analysis, x-ray
diffraction, thermogravimetry, differential thermal analysis, Raman scattering and electron
microscopy were used to characterize the material.
Moybdenum-based subnanometre diameter nanowires are easy to synthesize and disperse,
and they exhibit a variety of functional properties in which they are superior to other
one-dimensional materials. However, further progress in the understanding of
physical properties and the development of new and specific applications have so far
been impeded by the fact that their structure was not accurately known. Here
we report on a combination of systematic x-ray diffraction and extended x-ray
absorption fine structure experiments, and first-principles theoretical structure
calculations, which are used to determine the atomic skeletal structure of individual
Mo6S9−xIx (MoSIx) nanowires, their packing arrangement within bundles and their electronic band structure.
From this work we conclude that the variations in functional properties appear to arise
from different stoichiometry, not skeletal structure. A supplementary data file is available
from http://stacks.iop.org/0957-4484/16/1578
We present Raman scattering and scanning tunnelling microscopy (STM) measurements on hydrogen plasma etched single-wall carbon nanotubes (SWNTs). Interestingly, both the STM and Raman spectroscopy show that the metallic SWNTs are dramatically altered and highly defected by the plasma treatment. In addition, structural characterizations show that metal catalysts are detached from the ends of the SWNT bundles. For semiconducting SWNTs we observe no feature of defects or etching along the nanotubes. Raman spectra in the radial breathing mode region of plasma-treated SWNT material show that most of the tubes are semiconducting. These results show that hydrogen plasma treatment favours etching of metallic nanotubes over semiconducting ones and therefore could be used to tailor the electronic properties of SWNT raw materials.
Bundle of joy! The mechanical properties of Mo6S9−xIx nanowires with x=6 and 4.5 (see image) are investigated. Despite the identical atomic structures mechanical measurements based on deformation of suspended nanowires reveal more than a factor of two difference in the shear modulus, which indicates significant variation in the mechanical coupling between individual nanowires arising from different atomic species on the nanowire surface.
A new nanowire-like material with the chemical formula Mo 6 S 4.5 I 4.5 was studied as additive in a synthetic base oil, a polyalphaolefin (PAO). This material presents interesting friction reducing properties, with friction coefficients reaching a value of 0.04 in boundary lubrication. Transmission and scanning electron microscopy, X-ray diffraction, Raman spectroscopy and X-ray photoelectron spectroscopy were used to characterise nanowires before and after friction. The combination of these techniques gave evidence of MoS 2 formation in the contact area during friction tests. This structural evolution of nanowires explains their good friction reducing properties.
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