## Solid State PhysicsThis book provides an introduction to the field of solid state physics for undergraduate students in physics, chemistry, engineering, and materials science. |

### From inside the book

Results 1-3 of 77

Page 307

The d-bands are narrower than typical free electron conduction bands, and

contain enough levels to accommodate ten electrons. Since the d-bands contain

more levels in a narrower energy range, the

The d-bands are narrower than typical free electron conduction bands, and

contain enough levels to accommodate ten electrons. Since the d-bands contain

more levels in a narrower energy range, the

**density of levels**is likely to be ...Page 465

electron

alternative form (23.35) where the integral is over that surface in the first zone on

which cos(k) = a>. Just as in the electronic case, because cos(k) is periodic there

...

electron

**density of levels**, one can represent the phonon**density of levels**in thealternative form (23.35) where the integral is over that surface in the first zone on

which cos(k) = a>. Just as in the electronic case, because cos(k) is periodic there

...

Page 805

Debye frequency (ojd), 458 compared with Fermi energy, 529 Debye-Hiickel

theory, 342n of depletion layer, 611 Debye model of phonon spectrum, 457-461,

465-466

Debye frequency (ojd), 458 compared with Fermi energy, 529 Debye-Hiickel

theory, 342n of depletion layer, 611 Debye model of phonon spectrum, 457-461,

465-466

**density of levels**, 465-466 vs. Einstein model, 462-463 Griineisen ...### What people are saying - Write a review

We haven't found any reviews in the usual places.

### Contents

The Drude Theory of Metals | 1 |

The Sommerfeld Theory of Metals | 29 |

Failures of the Free Electron Model | 57 |

Copyright | |

49 other sections not shown

### Other editions - View all

Solid State Physics: Advances in Research and Applications, Volume 42 Henry Ehrenreich Limited preview - 1989 |

### Common terms and phrases

alkali atomic band structure Bloch boundary condition 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 described determined direction Drude effect electric field electron gas electron-electron electronic levels energy gap equilibrium example face-centered cubic Fermi energy Fermi surface Figure free electron theory frequency given Hamiltonian hexagonal holes impurity independent electron approximation insulators integral interaction ionic crystals lattice planes lattice point linear magnetic field metals motion nearly free electron neutron normal modes Note number of electrons one-electron levels orbits periodic potential perpendicular phonon Phys plane waves primitive cell primitive vectors problem properties quantum reciprocal lattice vector region result scattering Schrodinger equation semiclassical semiclassical equations semiclassical model semiconductors simple cubic solid solution specific heat sphere spin superconducting symmetry temperature term thermal tight-binding valence vanishes velocity wave functions wave vector zero