固态物理学基础

chapter 1 crystal structures and interatomic forces
　1.1 introduction
　1.2 the crystalline state
　1.3 basic definitions
　1.4 the fourteen bravais lattices and the seven crystalsystems
　1.5 elements of symmetry
　1.6 nomenclature of crystal directions and crystal planes; millerindices
　1.7 examples of simple crystal structures
　1.8 amorphous solids and liquids
　1.9 interatomic forces
　1.10 types of bonding
chapter 2 x-ray, neutron, and electron diffraction incrystals
　2.1 introduction
　2.2 generation and absorption of x-rays
　2.3 bragg's law
　2.4 scattering from an atom
　2.5 scattering from a crystal
　2.6 the reciprocal lattice and x-ray diffraction
　2.7 the diffraction condition and bragg's law
　2.8 scattering from liquids
　2.9 experimental techniques
　2.10 other x-ray applications in solid-state physics
　2.11 neutron diffraction
　2.12 electron diffraction
chapter 3 lattice vibrations: thermal, acoustic, and opticalproperties
　3.1 introduction
　3.2 elastic waves
　3.3 enumeration of modes; density of states of a continuousmedium
　3.4 specific heat: models of einstein and debye
　3.5 the phonon
　3.6 lattice waves
　3.7 density of states of a lattice
　3.8 specific heat: exact theory
　3.9 thermal conductivity
　3.10 scattering of x-rays, neutrons, and light by phonons
　3.11 microwave ultrasonics
　3.12 lattice optical properties in the infrared
chapter 4 metals i: the free. electron model
　4.1 introduction
　4.2 conduction electrons
　4.3 the free-electron gas
　4.4 electrical conductivity
　4.5 electrical resistivity versus temperature
　4.6 heat capacity of conduction electrons
　4.7 the fermi surface
　4.8 electrical conductivity; effects of the fermi surface
　4.9 thermal conductivity in metals
　4.10 motion in a magnetic field: cyclotron resonance and the halleffect
　4.11 the ac conductivity and optical properties
　4.12 thermionic emission
　4.13 failure of the free-electron model
chapter 5 metals il: energy bands in solids
　5.1 introduction
　5.2 energy spectra in atoms, molecules, and solids
　5.3 energy bands in solids; the bloch theorem
　5.4 band symmetry in k-space; brillouin zones
　5.5 number of states in the band
　5.6 the nearly-free-electron model
　5.7 the energy gap and the bragg reflection
　5.8 the tight-binding model
　5.9 calculations of energy bands
　5.10 metals, insulators, and semiconductors
　5.11 density of states
　5.12 the fermi surface
　5.13 velocity of the bloch electron
　5.14 electron dynamics in an electric field
　5.15 the dynamical effective mass
　5.16 momentum, crystal momentum, and physical origin of theeffective mass
　5.17 the hole
　5.18 electrical conductivity
　5.19 electron dynamics in a magnetic field: cyclotron resonanceand the hall effect
　5.20 experimental methods in determination of band structure
　5.21 limit of the band theory; metal-insulator transition
chapter 6 semiconductors i: theory
　6.1 introduction
　6.2 crystal structure and bonding
　6.3 band structure
　6.4 carrier concentration; intrinsic semiconductors
　6.5 impurity states
　6.6 semiconductor statistics
　6.7 electrical conductivity; mobility
　6.8 magnetic field effects: cyclotron resonance and halleffect
　6.9 band structure of real semiconductors
　6.10 high electric field and hot electrons
　6.11 the gunn effect
　6.12 optical properties: absorption processes
　6.13 photoconductivity
　6.14 luminescence
　6.15 other optical effects
　6.16 sound-wave amplification (acoustoelectric effect)
　6.17 diffusion
chapter 7 semiconductors ii: devices
　7.1 introduction
　7.2 the p-n junction: the rectifier
　7.3 the p-n junction: the junction itself
　7.4 the junction transistor
　7.5 the tunnel diode
　7.6 the gunn diode
　7.7 the semiconductor laser
　7.8 the field-effect transistor, the semiconductor lamp, and otherdevices
　7.9 integrated circuits and microelectronics
chapter 8 dielectric and optical properties of solids
　8.1 introduction
　8.2 review of basic formulas
　8.3 the dielectric constant and polarizability; the localfield
　8.4 sources of polarizability
　8.5 dipolar polarizability
　8.6 dipolar dispersion
　8.7 dipolar polarization in solids
　8.8 ionic polarizability
　8.9 electronic polarizability
　8.10 piezoelectricity
　8.11 ferroelectricity
chapter 9 magnetism and magnetic resonances
　9.1 introductio
　9.2 review of basic formulas
　9.3 magnetic susceptibility
　9.4 classification of materials
　9.5 langevin diamagnetism
　9.6 paramagnetism
　9.7 magnetism in metals
　9.8 ferromagnetism in insulators
　9.9 antiferromagnetism and ferrimagnetism
　9.10 ferromagnetism in metals
　9.11 ferromagnetic domains
　9.12 paramagnetic resonance; the maser
　9.13 nuclear magnetic resonance
　9.14 ferromagnetic resonance; spin waves
chapter 10 superconductivity
　10.1 introduction
　10.2 zero resistance
　10.3 perfect diamagnetism, or the meissner effect
　10.4 the critical field
　10.5 thermodynamics of the superconducting transition
　10.6 electrodynamics of superconductors
　10.7 theory of superconductivity
　10.8 tunneling and the josephson effect
　10.9 miscellaneous topics
chapter 11 topics in metallurgy and defects in solids
　11.1 introduction
　11.2 types of imperfections
　11.3 vacancies
　11.4 diffusion
　11.5 metallic alloys
　11.6 dislocations and the mechanical strength of metals
　11.7 lonic conductivity
　11.8 the photographic process
　11.9 radiation damage in solids
chapter 12 materials and solid-state chemistry
　12.1 introduction
　12.2 amorphous semiconductors
　12.3 liquid crystals
　12.4 polymers
　12.5 nuclear magnetic resonance in chemistry
　12.6 electron spin resonance in chemistry
　12.7 chemical applications of the msssbauer effect
chapter 13 solid.state biophysics
　13.1 introduction
　13.2 biological applications of delocalization in molecules
　13.3 nucleic acids
　13.4 proteins
　13.5 miscellaneous topics
appendix elements of quantum mechanics
　a.1 basic concepts
　a.2 the schrsdinger equation
　a.3 one-dimensional examples
　a.4 the angular momentum
　a.5 the hydrogen atom; multielectron atoms; periodic table of theel
　a.6 perturbation theory
　a.7 the hydrogen molecule and the covalent bond
　a.8 directed bonds
index