Page 189 - Carbon Nanotubes
P. 189
SUBJECT INDEX
acetylene source 15 fullerenes 87
AFRVI: see atomic force microscopy growth pathway 65
alkalUalkali earth metals 169 metal-coated 169
arc plasma, nanotube growth 11 multi-shell, synthesis 153
atomic force microscopy (AFM) 65 nanotubes comparison 15
fundamental parameters 27
band gap 37
band structure 37 geometry
buckybundles see buclqtubes carbon nanotubes 59
buckytubes 149 metal-coated fullerenes 169
properties 111 glow discharge, buckybundles 11 1
graphene layers, flexibility 149
cage forms 77 graphene model 37
cahon fibers 87 graphite structure 1
vapo-grown 1 graphitic carbon 77
carbon nanotubes see nanotubes; pyrolitic carbon graphitic particles, onion-like 153
nanotubes
carbon-carbon intralayer distance 59 helical forms 77
catalysis helix angle 59
growth mechanism 87 hemi-toroidal nanostructures 105
nanotubule production 15 high-resolution transmission electron microsopy
single-layer nanotubes 47 (HREM) 1,37, 111, 163
chiral nanotubes 27
clusters, metal-fullerenes 169 icosahedral layers 169
cobalt nanocrystals 153 incomplete bonding defects 7 1
cobalt particles 47 infrared studies 129
coiled carbon nanotubes 87 interlayer distance 59
iron nanocrystals 153
diameters, Mlerene-scale 15
dekcts 7 1 knee structures 87
disordered carbons 129
magnetic properties, buckytubes 11 1
electric field, nanotube growth 11 magnetoresistance 121
electrical properties 47 magnetic susceptibility 12 1
electrical resistivity 12 1 mass spectroscopy, metal-coated fullerenes 169
electron irradiation 163 mechanical properties 47, 143
electronic bands 27 metal particles 47
electronic properties 11 1 metal-coated fullerenes 169
carbon nanotubes 121 molecular dynamics 77
structure 37 multi-shell fullerenes 163
electronic shells 169 multi-shell tubes 65
multi-wall nanotubes 27
fiber-reinforced composites 143
fibers 47 nanocapsules 153
structures 65 nanocones, STM 65
