Electronic Structure and Properties: Treatise on Materials Science and Technology, Vol. 21, Volume 21Frank Y. Fradin Treatise on Materials Science and Technology, Volume 21: Electronic Structure and Properties covers the developments in electron theory and electron spectroscopies. The book discusses the electronic structure of perfect and defective solids; the photoelectron spectroscopy as an electronic structure probe; and the electron-phonon interaction. The text describes the elastic properties of transition metals; the electrical resistivity of metals; as well as the electronic structure of point defects in metals. Metallurgists, materials scientists, materials engineers, and students involved in the related fields will find the book useful. |
From inside the book
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Page 2
... equation characterized by a multicenter nonspherical potential. Aside from providing a rigorous basis and justification of the single-particle energy band description of the ground-state properties of materials, it has led to accurate ...
... equation characterized by a multicenter nonspherical potential. Aside from providing a rigorous basis and justification of the single-particle energy band description of the ground-state properties of materials, it has led to accurate ...
Page 3
... equation for 10” nuclei and electrons and is a completely hopeless task.) It is important to keep these approximations in mind as they are not completely justifiable and may affect seriously some of the physical results obtained. The ...
... equation for 10” nuclei and electrons and is a completely hopeless task.) It is important to keep these approximations in mind as they are not completely justifiable and may affect seriously some of the physical results obtained. The ...
Page 4
... equation with the assumed potential. High-speed computers, good mathematical analysis, and programming have made the second part of the problem relatively easy to solve and have led to considerable confidence in the numerical accuracy ...
... equation with the assumed potential. High-speed computers, good mathematical analysis, and programming have made the second part of the problem relatively easy to solve and have led to considerable confidence in the numerical accuracy ...
Page 6
... equation for the motion of an electron in a periodic potential. The great simplification introduced by exploiting the high symmetry of the crystal lattice makes possible the accurate solutions of these otherwise complex equations for a ...
... equation for the motion of an electron in a periodic potential. The great simplification introduced by exploiting the high symmetry of the crystal lattice makes possible the accurate solutions of these otherwise complex equations for a ...
Page 10
... equation inside the APW sphere. The wave-function coefficients A,(k) and eigenvalues can be determined by the Rayleigh–Ritz variational procedure as solutions of a standard eigenvalue problem, as discussed in Mattheiss et al. (1968) ...
... equation inside the APW sphere. The wave-function coefficients A,(k) and eigenvalues can be determined by the Rayleigh–Ritz variational procedure as solutions of a standard eigenvalue problem, as discussed in Mattheiss et al. (1968) ...
Contents
1 | |
Chapter 2 Photoelectron Spectroscopy as an Electronic Structure Probe | 99 |
Chapter 3 Electronic Structure and the ElectronPhonon Interaction | 165 |
Chapter 4 Elastic Properties of Transition Metals | 223 |
Chapter 5 Electrical Resistivity of Metals | 297 |
Chapter 6 Electronic Structure of Point Defects in Metals | 351 |
INDEX | 427 |
CONTENTS OF PREVIOUS VOLUMES | 441 |
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Common terms and phrases
alloys anomalies approximation atom band structure binding energy Brillouin zone bulk calculations charge density compounds conduction electrons contribution correlation Coulomb crystal curve d-band deformation potential e/at effect elastic constants electrical resistivity electron density electron gas electron-phonon interaction electronic structure energy band equation experiment experimental Fermi energy Fermi level Fermi surface ferromagnetic Freeman Friedel Friedel oscillations ground-state hybridization hydrogen impurity increase interstitial ions jellium jellium model Jena lattice Lett magnetic materials measured method moduli monovacancy muffin-tin muon obtained orbitals Papaconstantopoulos parameter peak phase phonon photoemission Phys point defects polarization positron properties proton pseudopotential rare-earth region sample scattering self-consistent shear shift shown in Fig shows Solid State Commun spectra Spectroscopy spin density strain Superconductivity temperature dependence theoretical theory tion transition metals transition-metal vacancy valence valence-band values variation velocity Wang wave functions York