Rafii-Tabar H. Computational physics of carbon nanotubes. - Cambridge: Cambridge University Press, 2008. - xi, 493 p.: ill. - Ref.: p.477-486. - Ind.: p.487-493. - ISBN 978-0-521-85300-2  Место хранения:   091 | Филиал Института физики полупроводников CO РАН | Oмск

Оглавление / Contents

Preface ........................................................ ix 1 Introduction ................................................. 1 Part I ......................................................... 13 2 Formation of carbon allotropes .............................. 15 2.1 Diamond ................................................ 18 2.2 Graphite ............................................... 19 2.3 Fullerenes ............................................. 22 2.4 Carbon nanotubes and nanohorns ......................... 23 3 Nanoscale numerical simulation techniques ................... 43 3.1 Essential concepts from classical statistical mechanics .............................................. 44 3.2 Key concepts underlying the classical molecular dynamics (MD) simulation method ........................ 61 3.3 Key concepts underlying the classical Monte Carlo (MC) simulation method ...................................... 71 3.4 Ab initio molecular dynamics simulation methods ........ 80 4 Interatomic potentials and force-fields in the computational physics of carbon nanotubes ............... 91 4.1 Interatomic potential energy function (PEF) ............ 91 4.2 Force-field (molecular mechanics) method ............... 94 4.3 Energetics of carbon nanotubes ......................... 95 4.4 Energetics of SWCNT-C60 and C60-C60 interactions ....... 106 4.5 Energetics of fluid flow through carbon nanotubes ..... 109 4.6 Energetics of gas adsorption inside carbon nanotubes and nanohorns ......................................... 119 5 Continuum elasticity theories for modelling the mechanical properties of nanotubes ..................... 135 5.1 Basic concepts from continuum elasticity theory ....... 135 5.2 Nonlinear thin-shell theories ......................... 152 5.3 Theories of curved plates ............................. 159 5.4 Theories of vibration, bending and buckling of beams ................................................. 166 6 Atomistic theories of mechanical properties ................ 186 6.1 Atomic-level stress tensor ............................ 186 6.2 Elastic constants from atomistic dynamics ............. 190 6.3 Bulk and Young's moduli ............................... 192 7 Theories for modelling thermal transport in nanotubes ...... 195 7.1 Thermal conductivity .................................. 195 7.2 Specific heat ......................................... 202 Part II ....................................................... 209 8 Modelling fluid flow in nanotubes .......................... 211 8.1 Modelling the influence of a nanotube's dynamics and length on the fluid flow .............................. 212 8.2 Modelling the flow of CH4 through SWCNTs .............. 215 8.3 Modelling self- and collective diffusivities of fluids in SWCNTs ...................................... 217 8.4 Modelling the capillary flow in an SWCNT .............. 219 8.5 Modelling the confinement and flow of liquid water inside SWCNTs ......................................... 221 8.6 Modelling the dynamics of C60@nanotubes ............... 223 9 Modelling gas adsorption in carbon nanotubes ............... 225 9.1 Atomic and molecular hydrogen in nanotubes ............ 225 9.2 Adsorption of rare gases in SWCNTs .................... 251 9.3 Adsorption of gases in the assemblies of SWCNHs ....... 264 10 Modelling the mechanical properties of carbon nanotubes .... 277 10.1 Modelling compression, bending, buckling, vibration, torsion and fracture of nanotubes ..................... 279 10.2 Modelling the elastic properties of SWCNTs and MWCNTs ................................................ 383 10.3 Stress-strain properties of nanotubes ................. 416 10.4 Validity of application of continuum-based theories to model the mechanical properties of nanotubes ....... 439 11 Modelling the thermal properties of carbon nanotubes ....... 450 11.1 Computation of thermal conductivity ................... 451 11.2 Specific heat of nanotubes ............................ 468 References .................................................... 477 Index ......................................................... 487