Classical ElectrodynamicsEin Klassiker im neuen Gewand! Diese Neuauflage behandelt in bekannter verständlicher und umfassender Weise alle Grundlagen und fortgeschrittenen Aspekte der klassischen und semiklassischen Elektrodynamik und wurde darüber hinaus um die Neuheiten der vergangenen zwanzig Jahre - Synchrotronstrahlung, Undulatoren, Wiggler,... - ergänzt. Ebenfalls besprochen werden die Grundgedanken numerischer Methoden der Elektrostatik und Magnetostatik, so daß der Leser die theoretische Basis einschlägiger Computerprogramme verstehen lernt. (01/99) |
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Page xv
... Chapter 1 / Introduction to Electrostatics 1.1 Coulomb's Law 24 1.2 Electric Field 24 1.3 Gauss's Law 27 1.4 Differential Form of Gauss's Law 28 1.5 Another Equation of Electrostatics and the Scalar Potential 1.6 Surface Distributions ...
... Chapter 1 / Introduction to Electrostatics 1.1 Coulomb's Law 24 1.2 Electric Field 24 1.3 Gauss's Law 27 1.4 Differential Form of Gauss's Law 28 1.5 Another Equation of Electrostatics and the Scalar Potential 1.6 Surface Distributions ...
Page xvii
... Chapter 6 / Maxwell Equations , Macroscopic Electromagnetism , Conservation Laws 237 Maxwell's Displacement Current ; Maxwell Equations 237 Vector and Scalar Potentials 239 Gauge Transformations , Lorenz Gauge , Coulomb Gauge 240 Green ...
... Chapter 6 / Maxwell Equations , Macroscopic Electromagnetism , Conservation Laws 237 Maxwell's Displacement Current ; Maxwell Equations 237 Vector and Scalar Potentials 239 Gauge Transformations , Lorenz Gauge , Coulomb Gauge 240 Green ...
Page xviii
... Chapter 8 / Waveguides , Resonant Cavities , and Optical Fibers 8.1 Fields at the Surface of and Within a Conductor 352 8.2 Cylindrical Cavities and Waveguides 356 8.3 Waveguides 359 8.4 Modes in a Rectangular Waveguide 361 8.5 Energy ...
... Chapter 8 / Waveguides , Resonant Cavities , and Optical Fibers 8.1 Fields at the Surface of and Within a Conductor 352 8.2 Cylindrical Cavities and Waveguides 356 8.3 Waveguides 359 8.4 Modes in a Rectangular Waveguide 361 8.5 Energy ...
Page xix
... Chapter 10 / Scattering and Diffraction 10.1 Scattering at Long Wavelengths 456 10.2 Perturbation Theory of Scattering , Rayleigh's Explanation of the Blue Sky , Scattering by Gases and Liquids , Attenuation in Optical Fibers 462 10.3 ...
... Chapter 10 / Scattering and Diffraction 10.1 Scattering at Long Wavelengths 456 10.2 Perturbation Theory of Scattering , Rayleigh's Explanation of the Blue Sky , Scattering by Gases and Liquids , Attenuation in Optical Fibers 462 10.3 ...
Page xx
... Chapter 13 / Collisions , Energy Loss , and Scattering of Charged Particles , Cherenkov and Transition Radiation 624 13.1 Energy Transfer in Coulomb Collision Between Heavy Incident Particle and Free Electron ; Energy Loss in Hard ...
... Chapter 13 / Collisions , Energy Loss , and Scattering of Charged Particles , Cherenkov and Transition Radiation 624 13.1 Energy Transfer in Coulomb Collision Between Heavy Incident Particle and Free Electron ; Energy Loss in Hard ...
Contents
II | 95 |
Yime o | 107 |
Multipoles Electrostatics of Macroscopic Media | 145 |
Magnetostatics Faradays Law QuasiStatic Fields | 174 |
with an Asymptotically Uniform Tangential Magnetic Field | 203 |
Maxwell Equations Macroscopic Electromagnetism | 237 |
6 | 286 |
Plane Electromagnetic Waves and Wave Propagation | 295 |
External Fields | 561 |
Dynamics of Relativistic Particles | 579 |
Collisions Energy Loss and Scattering of Charged Particles | 624 |
Radiation by Moving Charges | 661 |
Bremsstrahlung Method of Virtual Quanta | 708 |
Radiation Damping Classical Models | 745 |
Appendix on Units and Dimensions | 775 |
785 | |
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angle angular approximation assumed atomic average axis becomes boundary conditions calculation Chapter charge classical collision compared components conducting conductor consider constant contribution coordinates cross section defined density dependence derivative determined dielectric dimensions dipole direction discussed distance distribution effects electric field electromagnetic electron energy equal equation example expansion expression factor Figure force frame frequency function given gives incident induction inside integral light limit linear Lorentz magnetic field mass means medium modes momentum motion moving multipole normal observation obtain origin parallel particle photon physical plane polarization position potential Problem properties quantum mechanics radiation radius region relation relative result scalar scattering Show shown side solution space special relativity sphere spherical surface transformation unit vanishes vector velocity volume wave written zero