Applied Electromagnetism and MaterialsApplied Electromagnetism and Materials picks up where Basic Electromagnetism and Materials left off by presenting practical and relevant technological information about electromagnetic material properties and their applications. This book is aimed at senior undergraduate and graduate students as well as researchers in materials science and is the product of many years of teaching basic and applied electromagnetism. Topics range from the spectroscopy and characterization of dielectrics and semiconductors, to non-linear effects and electromagnetic cavities, to ion-beam applications in materials science. |
Contents
Characterization of dielectrics | 39 |
Spectroscopy of dielectrics and the KrönigKramers | 71 |
Interactions of electromagnetic waves and solid semi | 111 |
reflectivity gap size | 128 |
Level of absorption and emission | 139 |
Problem | 145 |
Einsteins relation | 152 |
Introduction to nonlinear effects | 181 |
Electromagnetic cavities | 207 |
Electromagnetic processes applied to a largescale | 265 |
Electromagnetic ionmaterial interactions 295 | 294 |
| 341 | |
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Common terms and phrases
² ² absorption angle angular frequency associated axis calculation carriers cathode cavity Chapter circuit coefficient collisions component condenser conduction band constant corresponds coulombic current density Debye deduced defined denoted dephasing determine dielectric permittivity dipole direction displacement effect electric field electromagnetic electrostatic lens emission equation equilibrium equipotential expression Faraday cage forbidden band function G G G given gives rise hence holes incident ion incident particle increases inelastic collisions interaction ionization JJJJG Laplace force lattice magnetic field mass material n-type semiconductor nuclei obtain optical parallel permittivity photon plots Pockels effect possible potential energy problem regime relaxation representation resonance respect result Section semiconductor shown in Figure stopping power target atom tension trajectory transition valence band vector velocity volume wave Wien filter zero zone