We report on the synthesis, structure, and self-assembly of single-wall subnanometer-diameter molybdenum disulfide tubes. The nanotubes are up to hundreds of micrometers long and display diverse self-assembly properties on different length scales, ranging from twisted bundles to regularly shaped "furry" forms. The bundles, which contain interstitial iodine, can be readily disassembled into individual molybdenum disulfide nanotubes. The synthesis was performed using a novel type of catalyzed transport reaction including C(60) as a growth promoter.
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.
pressure increases on the downstream side. A specimen for transmission electron microscopy (TEM) was prepared by sectioning a hybrid nanocomposite containing 10 wt.-% FS at ±100 C in a Reichert-Jung cryo-ultramicrotome. Electron-transparent sections measuring ca. 80 nm thick were imaged with a Zeiss EM902 electron spectroscopic microscope operated at an accelerating voltage of 80 kV and an energy loss of 0 eV. In the past decade, the discovery of fullerenes and carbon nanotubes as new forms of carbon has prompted the opening of an interesting and dynamic new field in physics, chemistry, and materials science because of their remarkable properties and a wide range of potential applications. With the discovery of tungsten disulfide (WS 2 ) and molybdenum disulfide (MoS 2 ) fullerene-like nanoparticles and tubular structures, [1,2] followed by the discovery of boron nitride (BN) nanotubes, [3] it was realized that fullerenes and carbon nanotubes represent only a small subset of a wide class of layered materials that can form C 60 -like particles, tubes, and other interesting morphologies.MoS 2 can be synthesized in a large variety of formsÐparti-cles, nanotubes, [1,2] multiwalled nanotubes [4] and alsoÐlike their carbon cousinsÐin the form of ropes, ribbons, and thin microtubes several micrometers in diameter and millimeters in length. [5] This richness in form promises potential applications going beyond those of carbon nanotubes. Recent theoretical calculations [6] predicted that MoS 2 nanotubes with diameters above 2 nm will all be semiconductors with a bandgap smaller than that of bulk MoS 2 . The size of this gap is a monotonous and smooth function of the tube's diameter and chirality. Zigzag tubes would even have a small direct gap, suggesting that they could be used for optoelectronics i.e., luminescent devices, which is not possible for carbon nanotubes. At this time, there are no theoretical calculations available on MoS 2 nanotubes with subnanometer diameters, such as the ones used in this study. Nevertheless, recent experimental findings indicate that these tubes are most likely all metallic. [7,8] Carbon nanotubes are always produced with a distribution of diameters and chiralities over which there is no real control. As a consequence, they have diverse electronic properties: semiconducting p-and n-tubes are produced along with metallic ones. Even a small change of diameter can drastically alter their electronic properties from metallic to semiconducting. In order to control the electronic properties of carbon nanotubes during production, complete control over their diameters is neededÐa feat that has not been achieved yet. A narrow distribution of diameter will still yield a mixture of metallic and semiconducting tubes. MoS 2 nanotubes on the other hand do not require perfect control over their diameters, because they are predicted to be semiconductors with a monotonous dependence of the bandgap on the diameter. Thanks to this, perfect control over their diameter is not needed: a narrow di...
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