Solid State PhysicsThis book provides an introduction to the field of solid state physics for undergraduate students in physics, chemistry, engineering, and materials science. |
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Page 86
... satisfying eK.R 1 ( 5.2 ) . ( r + R ) = ekor iKT for all R in the Bravais lattice . Note that a reciprocal lattice is ... satisfy ( 5.2 ) , so , obviously , will their sum and difference . It is worth considering a more clumsy proof of ...
... satisfying eK.R 1 ( 5.2 ) . ( r + R ) = ekor iKT for all R in the Bravais lattice . Note that a reciprocal lattice is ... satisfy ( 5.2 ) , so , obviously , will their sum and difference . It is worth considering a more clumsy proof of ...
Page 178
... satisfies the atomic Schrödinger equation ( 10.1 ) , then it will also satisfy the crystal Schrödinger equation ( 10.2 ) , provided that AU ( r ) vanishes wherever ( r ) does not . If this were indeed the case , then each atomic level ...
... satisfies the atomic Schrödinger equation ( 10.1 ) , then it will also satisfy the crystal Schrödinger equation ( 10.2 ) , provided that AU ( r ) vanishes wherever ( r ) does not . If this were indeed the case , then each atomic level ...
Page 201
... satisfy the atomic Schrödinger equation : h2 2m - V2ke ( r ) + V ( r R ) ( r ) = && ( r ) , r - Rro Rro ( 11.15 ) ... satisfies not ( 11.15 ) but Hok.ɛ = ( h2k2 / 2m ) . Note also that , in general , will have a discontinuous derivative on ...
... satisfy the atomic Schrödinger equation : h2 2m - V2ke ( r ) + V ( r R ) ( r ) = && ( r ) , r - Rro Rro ( 11.15 ) ... satisfies not ( 11.15 ) but Hok.ɛ = ( h2k2 / 2m ) . Note also that , in general , will have a discontinuous derivative on ...
Contents
The Drude Theory of Metals | 1 |
The Sommerfeld Theory of Metals | 29 |
Failures of the Free Electron Model | 57 |
Copyright | |
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alkali atomic band structure Bloch Bragg plane Bravais lattice Brillouin zone calculation carrier densities Chapter coefficients collisions conduction band conduction electrons contribution crystal momentum crystal structure density of levels dependence depletion layer described dielectric constant distribution Drude Drude model effect electric field electron gas electron-electron electronic levels electrostatic energy gap equilibrium example Fermi energy Fermi surface Figure free electron frequency given Hamiltonian hexagonal holes impurity independent electron approximation insulators interaction ionic crystals k-space lattice planes lattice point linear low temperatures macroscopic magnetic field metals neutron normal modes number of electrons one-electron levels orbits periodic potential perpendicular phonon Phys primitive cell primitive vectors Problem properties quantum reciprocal lattice vector region result scattering Schrödinger equation semiclassical semiconductors simple cubic solid solution specific heat spin superconducting symmetry term theory thermal valence band vanishes velocity wave functions wave vector zero