Electronic Properties of Crystalline Solids: An Introduction to Fundamentals

absorption constant acceptor acoustic allowed energy approximation atoms bandgap Bloch boundary conditions Brillouin zone calculation capture coefficient conduction band considered corresponding cross section crystal current density described direct transition distribution donors effective mass eigenfunctions electric field electrical conductivity electrons and holes emission energy bands energy levels example excitation exciton expression Fermi energy Fermi level free carriers free electrons frequency function given in Eq given in Fig Hamiltonian hydrogenic impurity integral interaction involving ionization energy lattice waves lifetime magnetic field magnitude material matrix element maximum metal mobility momentum n-type obtain one-dimensional operator optical absorption orbit p-n junction particle periodic potential perturbation phonon photoconductivity photoexcitation Phys probability quantization reciprocal lattice recombination relaxation result scattering process Schroedinger equation semiconductor shown in Fig solution space spherical equal-energy surfaces temperature dependence thermal tion unit cell valence band variation velocity voltage wave equation wave vector wavefunction wavelength zero