Perspectives of Fullerene Nanotechnology |
Contents
| 3 | |
Some Aspects of Fullerene Application 23 | 21 |
Field Emission Microscopy of Carbon Nanotubes 49 | 48 |
Thin Film Carbon Nanotube Cathodes for Field Emission | 66 |
Selfassembly of Inorganic Nanotubes Synthesized by | 112 |
FTICR Reaction Experiments and Molecular Dynamics | 131 |
Application and Commercial Prospects of Fullerenes | 144 |
Free Radical Scavenging and Photodynamic Functions | 164 |
Ultrananocrystalline Diamond Films from Fullerene Precursors | 217 |
Properties and Applications of Superhard and Ultrahard Fullerites | 223 |
Formation of Nanostructured Carbons under | 253 |
Advanced Thermal Protection Coating Using Fullerenes 267 | 266 |
GasPhase Hydrogenation of Fullernes | 281 |
Use of Fullerenes and Carbon Nanotubes for Fabrication | 305 |
Physical Hydrogen Storage on Nanotubes and Nanocarbon Materials | 327 |
Nanotubes as Anode Material for Lithiumion Batteries 341 | 340 |
Sonodynamic Effect of Polyethylene glycolconjugated | 185 |
Mechanical Properties of Polymerized Amorphous | 198 |
Fullerene Materials for Lithiumion Battery Applications | 357 |
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Common terms and phrases
2002 Kluwer Academic activated carbon adsorbed adsorption aligned amorphous anode applications arc-produced as-produced atoms C60-PEG conjugate carbon fibers carbon materials carbon nanotubes catalyst cathode cells Chem chemical chemical vapor deposition clusters composites compounds conducting polymers density deposition diameter diamond films DWNT effect electrochemical electron emitter experimental FC4S fibers field emission formation fullerene Fullerene Nanotechnology fullerite graphene graphite growth heat hydrogen storage Hydrothermal ibid Iijima increase intercalation irradiation irreversible capacity laser layers Lett lithium lithium-ion mAh/g mechanical metal method molecular molecules MoS2 multiwall MWNT nanofibers nanostructures Nanotechnology obtained oxidation oxygen parameters particles Perspectives of Fullerene phases Phys polycarbonate polymerized pore porous carbons potential pressure produced properties reaction samples shown in Figure shungite rocks single-wall single-wall nanotubes structure substrate superhard surface area SWNT synthesis temperature thermal tion tubes tumor ultrahard fullerite vapor VGCFs voltage X-ray