The structure of the carbon nanotube and its surface topography probed by transmission electron microscopy and atomic force microscopy
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Synthesis and electro-catalytic activity of methanol oxidation on nitrogen containing carbon nanotubes supported Pt electrodes
2008, Applied Catalysis B: EnvironmentalNitrogen containing carbon nanotubes as supports for Pt - Alternate anodes for fuel cell applications
2005, Electrochemistry CommunicationsNew group structures for carbon onions and carbon nanotubes via affine extensions of non-crystallographic Coxeter groups
2002, Physics Letters, Section A: General, Atomic and Solid State PhysicsScrolls and nested tubes in multiwall carbon nanotubes
2002, CarbonCitation Excerpt :Among various analytical techniques, HREM has clearly been the most applied technique for studying the intricate structure of MWCNTs in detail, providing information on how the tubes are stacked, the nature of defects, and the structure of internal as well as external closures [15]. Other analytical methods have been also used for the structural characterization of MWCNTs: X-ray diffraction for crystallographic measurements [16], scanning probe microscopy for surface topography at the atomic scale [17], and electron diffraction to analyze the internal structure on a detailed basis [18]. Visual inspection of a large number of HREM images of MWCNTs clearly illustrates that these materials have a highly complex structure fraught with numerous defects.
The encapsulation and in situ rearrangement of polycrystalline SnO inside carbon nanotubes
1997, Journal of Crystal Growth