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One Book:Carbon Nanotubes: From Basic Research to Nanotechnology(2006 Springer)
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Carbon Nanotubes: From Basic Research to Nanotechnology TABLE OF CONTENTS Part I. Synthesis and structural characterization 1¡¢Arc discharge and laser ablation synthesis of single-walled carbon nanotubes(p1) 2¡¢Scanning tunneling microscopy and spectroscopy of carbon nanotubes(p19) 3¡¢Structural determination of individual singlewall carbon nanotube by nanoarea electron diffraction(p43) 4¡¢The structural effects on multi-walled carbon nanotubes by thermal annealing under vacuum(p45) 5¡¢TEM sample preparation for studying the interface CNTs-catalyst-substrate(p47) 6¡¢A method to synthesize and tailor carbon nanotubes by electron irradiation in the TEM(p49) 7¡¢Scanning tunneling microscopy studies of nanotube-like structures on the HOPG surface(p51) 8¡¢Influence of catalyst and carbon source on the synthesis of carbon nanotubes in a semi-continuous injection chemical vapor deposition method(p53) 9¡¢PECVD growth of carbon nanotubes(p55) 10¡¢Carbon nanotubes growth and anchorage to carbon fibres(p57) 11¡¢CVD synthesis of carbon nanotubes on different substrates(p59) 12¡¢Influence of the substrate types and treatments on carbon nanotube growth by chemical vapor deposition with nickel catalyst(p61) 13¡¢Non catalytic CVD growth of 2D-aligned carbon nanotubes.(p.63) 14¡¢Pyrolytic synthesis of carbon nanotubes on Ni, Co, Fe/-41 catalysts(p65) 15¡¢A Grand Canonical Monte Carlo simulation study of carbon structural and adsorption properties of in-zeolite templated carbon nanostructures(p67) Part II. Vibrational properties and optical spectroscopies 16¡¢Vibrational and related properties of carbon nanotubes(p69) 17¡¢Raman scattering of carbon nanotubes(p89) 18¡¢Raman spectroscopy of isolated single-walled carbon nanotubes(p121) Part III. Electronic and optical properties and electrical transport 19¡¢Electronic transport in nanotubes and through junctions of nanotubes(p123) 20¡¢Electronic transport in carbon nanotubes at the mesoscopic scale(p143) 21¡¢Wave packet dynamical investigation of STM imaging mechanism 22¡¢using an atomic pseudopotential model of a carbon nanotube(p167) 23¡¢Carbon nanotube films for optical absorption(p169) 24¡¢Intersubband exciton relaxation dynamics in single-walled carbon nanotubes(p171) 25¡¢Peculiarities of the optical polarizability of single-walled zigzag carbon nanotube with capped and tapered ends(p173) 26¡¢Third-order nonlinearity and plasmon properties in carbon nanotubes(p175) 27¡¢Hydrodynamic modeling of fast ion interactions with carbon nanotubes(p177) 28¡¢Local resistance of single-walled carbon nanotubes as measured by scanning probe techniques(p179) 29¡¢Band structure of carbon nanotubes embedded in a crystal matrix(p181) 30¡¢Magnetotransport in 2-D arrays of single-wall carbon nanotubes(p183) 31¡¢Computer modeling of the differential conductance of symmetry connected armchair-zigzag heterojunctions(p185) Part IV. Molecule adsorption, functionalization and chemical properties 32¡¢Molecular Dynamics simulation of gas adsorption and absorption in nanotubes(p187) 33¡¢First-principles and molecular dynamics simulations of methane adsorption on graphene(p209) 34¡¢Effect of solvent and dispersant on the bundle dissociation of single-walled carbon nanotubes(p211) 35¡¢Carbon nanotubes with vacancies under external mechanical stress and electric field(p213) Part V. Mechanical properties of nanotubes and composite materials 36¡¢Mechanical properties of three-terminal nanotube junction determined from computer simulations(p215) 37¡¢Oscillation of the charged doublewall carbon nanotube(p217) 38¡¢Polymer chains behavior in nanotubes: a Monte Carlo study(p219) 39¡¢Carbon nanotubes as ceramic matrix reinforcements(p221) 40¡¢Carbon nanotubes as polymer building blocks(p223) 41¡¢Synthesis and characterization of epoxy-single-wall carbon nanotube composites(p225) 42¡¢Vapour grown carbon nano-fibers ¨C polypropylene composites and their properties(p227) Part VI. Applications 43¡¢Nanotechnology: challenges of convergence, heterogeneity and hierarchical integration(p229) 44¡¢Behavior of carbon nanotubes in biological systems(p231) 45¡¢Molecular dynamics of carbon nanotube-polypeptide complexes at the biomembrane-water interface(p233) 46¡¢Thermal conductivity enhancement of nanofluids(p235) 47¡¢Carbon nanotubes as advanced lubricant additives(p237) 48¡¢Synthesis and characterization of iron nanostructures inside porous zeolites and their applications in water treatment technologies(p239) 49¡¢Nanostructured carbon growth by an expanding radiofrequency plasma jet(p241) 50¡¢Design and relative stability of multicomponent nanowires(p243) 51¡¢Modeling of molecular orbital and solid state packing polymer calculations on the bi-polaron nature of conducting sensor poly (p-phenylene) (p245) 52¡¢Nd:LSB microchip laser as a promising instrument for Raman spectroscopy(p247) Subject Index¡...¡¡..¡¡¡¡¡¡¡¡¡¡¡¡¡¡¡¡¡¡¡¡ 249 Author Index¡¡..¡¡¡¡¡¡¡¡¡¡¡¡¡¡¡¡¡¡¡¡¡¡ 251 |
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