05559nam 2200721 450 991082536540332120231110215420.03-527-67670-83-527-67666-X3-527-67671-6(CKB)2550000001123450(EBL)1424345(OCoLC)862795167(SSID)ssj0001107733(PQKBManifestationID)11717317(PQKBTitleCode)TC0001107733(PQKBWorkID)11085087(PQKB)11089352(MiAaPQ)EBC1424345(Au-PeEL)EBL1424345(CaPaEBR)ebr10774368(CaONFJC)MIL525167(MiAaPQ)EBC7104677(Au-PeEL)EBL7104677(JP-MeL)3000110952(EXLCZ)99255000000112345020131017h20132013 uy| 0engurcnu||||||||txtccrElectrical conduction in graphene and nanotubes /Shigeji Fujita and Akira SuzukiWeinheim, Germany :Wiley-VCH Verlag GmbH & Co. KGaA,[2013]20131 online resource (308 p.)Physics textbookDescription based upon print version of record.3-527-41151-8 1-299-93916-3 Includes bibliographical references and index.Electrical Conduction in Graphene and Nanotubes; Contents; Preface; Physical Constants, Units, Mathematical Signs and Symbols; 1 Introduction; 1.1 Carbon Nanotubes; 1.2 Theoretical Background; 1.2.1 Metals and Conduction Electrons; 1.2.2 Quantum Mechanics; 1.2.3 Heisenberg Uncertainty Principle; 1.2.4 Bosons and Fermions; 1.2.5 Fermi and Bose Distribution Functions; 1.2.6 Composite Particles; 1.2.7 Quasifree Electron Model; 1.2.8 "Electrons" and "Holes"; 1.2.9 The Gate Field Effect; 1.3 Book Layout; 1.4 Suggestions for Readers; 1.4.1 Second Quantization1.4.2 Semi-classical Theory of Electron Dynamics 1.4.3 Fermi Surface; References; 2 Kinetic Theory and the Boltzmann Equation; 2.1 Diffusion and Thermal Conduction; 2.2 Collision Rate: Mean Free Path; 2.3 Electrical Conductivity and Matthiessen's Rule; 2.4 The Hall Effect: "Electrons" and "Holes"; 2.5 The Boltzmann Equation; 2.6 The Current Relaxation Rate; References; 3 Bloch Electron Dynamics; 3.1 Bloch Theorem in One Dimension; 3.2 The Kronig-Penney Model; 3.3 Bloch Theorem in Three Dimensions; 3.4 Fermi Liquid Model; 3.5 The Fermi Surface; 3.6 Heat Capacity and Density of States3.7 The Density of State in the Momentum Space 3.8 Equations of Motion for a Bloch Electron; References; 4 Phonons and Electron-Phonon Interaction; 4.1 Phonons and Lattice Dynamics; 4.2 Van Hove Singularities; 4.2.1 Particles on a Stretched String (Coupled Harmonic Oscillators); 4.2.2 Low-Frequency Phonons; 4.2.3 Discussion; 4.3 Electron-Phonon Interaction; 4.4 Phonon-Exchange Attraction; References; 5 Electrical Conductivity of Multiwalled Nanotubes; 5.1 Introduction; 5.2 Graphene; 5.3 Lattice Stability and Reflection Symmetry; 5.4 Single-Wall Nanotubes; 5.5 Multiwalled Nanotubes5.6 Summary and Discussion References; 6 Semiconducting SWNTs; 6.1 Introduction; 6.2 Single-Wall Nanotubes; 6.3 Summary and Discussion; References; 7 Superconductivity; 7.1 Basic Properties of a Superconductor; 7.1.1 Zero Resistance; 7.1.2 Meissner Effect; 7.1.3 Ring Supercurrent and Flux Quantization; 7.1.4 Josephson Effects; 7.1.5 Energy Gap; 7.1.6 Sharp Phase Change; 7.2 Occurrence of a Superconductor; 7.2.1 Elemental Superconductors; 7.2.2 Compound Superconductors; 7.2.3 High-Tc Superconductors; 7.3 Theoretical Survey; 7.3.1 The Cause of Superconductivity7.3.2 The Bardeen-Cooper-Schrieffer Theory 7.3.3 Quantum Statistical Theory; 7.4 Quantum Statistical Theory of Superconductivity; 7.4.1 The Generalized BCS Hamiltonian; 7.5 The Cooper Pair Problem; 7.6 Moving Pairons; 7.7 The BCS Ground State; 7.7.1 The Reduced Generalized BCS Hamiltonian; 7.7.2 The Ground State; 7.8 Remarks; 7.8.1 The Nature of the Reduced Hamiltonian; 7.8.2 Binding Energy per Pairon; 7.8.3 The Energy Gap; 7.8.4 The Energy Gap Equation; 7.8.5 Neutral Supercondensate; 7.8.6 Cooper Pairs (Pairons); 7.8.7 Formation of a Supercondensate and Occurrence of Superconductors7.8.8 Blurred Fermi SurfaceWritten in a self-contained manner, this textbook allows both advanced students and practicing applied physicists and engineers to learn the relevant aspects from the bottom up. All logical steps are laid out without omitting steps.The book covers electrical transport properties in carbon based materials by dealing with statistical mechanics of carbon nanotubes and graphene presenting many fresh and sometimes provoking views. Both second quantization and superconductivity are covered and discussed thoroughly. An extensive list of references is given in the end of each chapter, whileNew York Academy of Sciences GrapheneElectric propertiesNanotubesElectric propertiesGrapheneElectric properties.NanotubesElectric properties.308Fujita Shigeji47005Suzuki Akira1688127MiAaPQMiAaPQMiAaPQBOOK9910825365403321Electrical conduction in graphene and nanotubes4062106UNINA