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Classical Electrodynamics captures Schwinger's inimitable lecturing style, in which everything flows inexorably from what has gone before.
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Classical Electrodynamics captures Schwinger's inimitable lecturing style, in which everything flows inexorably from what has gone before.
Produktdetails
- Produktdetails
- Frontiers in Physics
- Verlag: Taylor & Francis Inc
- Seitenzahl: 596
- Erscheinungstermin: 11. September 1998
- Englisch
- Abmessung: 229mm x 152mm x 37mm
- Gewicht: 1036g
- ISBN-13: 9780738200569
- ISBN-10: 0738200565
- Artikelnr.: 22846671
- Frontiers in Physics
- Verlag: Taylor & Francis Inc
- Seitenzahl: 596
- Erscheinungstermin: 11. September 1998
- Englisch
- Abmessung: 229mm x 152mm x 37mm
- Gewicht: 1036g
- ISBN-13: 9780738200569
- ISBN-10: 0738200565
- Artikelnr.: 22846671
"The late Julian Schwinger shared the 1965 Nobel Prize for Physics with Richard Feynman and Sin-ltiro Tomonaga for their work on the theory of quantum electrodynamics. Lester L. DeRaad, Jr. is Senior Research Specialist at Logicon RDA. Kimball A. Milton is Professor of Physics at the University of Oklahoma, Norman. Wu-yang Tsai is Scatterometer Project Engineer and Group Supervisor at the Jet Propulsion Laboratory in Pasadena, California."
Preface
Reader's Guide
1 Maxwell's Equations
2 Magnetic Charge I
3 Conservation Laws
4 Macroscopic Electrodynamics
5 Simple Model for Constitutive Relations
6 Magnetic Properties of Matter
7 Macroscopic Energy and Momentum
8 Review of Action Principles
9 Action Principle for Electrodynamics
10 Einsteinian Relativity
11 Stationary Principles for Electrostatics
12 Introduction to Green's Functions
13 Electrostatics in Free Space
14 Semi-Infinite Dielectric
15 Application of Green's Function
16 Bessel Functions
17 Parallel Conducting Plates
18 Modified Bessel Functions
19 Cylindrical Conductors
20 Spherical Harmonics
21 Coulomb's Potential
22 Multipoles
23 Conducting and Dielectric Spheres
24 Dielectrics and Conductors
25 Modes and Variations
26 Magnetostatics
27 Macroscopic Current Distributions
28 Magnetic Multipoles
29 Magnetic Scalar Potential
30 Magnetic Charge II
31 Retarded Green's Function
32 Radiation-Field Point of View
33 Radiation-Source Point of View
34 Models of Antennas
35 Spectral Distribution of Radiation
36 Power Spectrum and Cerenkov Radiation
37 Constant Acceleration and Impulse
38 Synchrotron Radiation I
39 Synchrotron Radiation II-Polarization
40 Synchrotron Radiation III-High Energies
41 Propagation in a Dielectric Medium
42 Reflection by an Imperfect Conductor
43 Cylindrical Coordinates
44 Waveguides
45 Scattering by Small Obstacles
46 Partial-Wave Analysis of Scattering
4 7 Diffraction I
48 Diffraction II
49 Babinet's Principle
50 General Scattering
51 Dispersion Relations for the Susceptibility
52 Charged Particle Energy Loss
A Units
B Bibliography
Index
Reader's Guide
1 Maxwell's Equations
2 Magnetic Charge I
3 Conservation Laws
4 Macroscopic Electrodynamics
5 Simple Model for Constitutive Relations
6 Magnetic Properties of Matter
7 Macroscopic Energy and Momentum
8 Review of Action Principles
9 Action Principle for Electrodynamics
10 Einsteinian Relativity
11 Stationary Principles for Electrostatics
12 Introduction to Green's Functions
13 Electrostatics in Free Space
14 Semi-Infinite Dielectric
15 Application of Green's Function
16 Bessel Functions
17 Parallel Conducting Plates
18 Modified Bessel Functions
19 Cylindrical Conductors
20 Spherical Harmonics
21 Coulomb's Potential
22 Multipoles
23 Conducting and Dielectric Spheres
24 Dielectrics and Conductors
25 Modes and Variations
26 Magnetostatics
27 Macroscopic Current Distributions
28 Magnetic Multipoles
29 Magnetic Scalar Potential
30 Magnetic Charge II
31 Retarded Green's Function
32 Radiation-Field Point of View
33 Radiation-Source Point of View
34 Models of Antennas
35 Spectral Distribution of Radiation
36 Power Spectrum and Cerenkov Radiation
37 Constant Acceleration and Impulse
38 Synchrotron Radiation I
39 Synchrotron Radiation II-Polarization
40 Synchrotron Radiation III-High Energies
41 Propagation in a Dielectric Medium
42 Reflection by an Imperfect Conductor
43 Cylindrical Coordinates
44 Waveguides
45 Scattering by Small Obstacles
46 Partial-Wave Analysis of Scattering
4 7 Diffraction I
48 Diffraction II
49 Babinet's Principle
50 General Scattering
51 Dispersion Relations for the Susceptibility
52 Charged Particle Energy Loss
A Units
B Bibliography
Index
Preface
Reader's Guide
1 Maxwell's Equations
2 Magnetic Charge I
3 Conservation Laws
4 Macroscopic Electrodynamics
5 Simple Model for Constitutive Relations
6 Magnetic Properties of Matter
7 Macroscopic Energy and Momentum
8 Review of Action Principles
9 Action Principle for Electrodynamics
10 Einsteinian Relativity
11 Stationary Principles for Electrostatics
12 Introduction to Green's Functions
13 Electrostatics in Free Space
14 Semi-Infinite Dielectric
15 Application of Green's Function
16 Bessel Functions
17 Parallel Conducting Plates
18 Modified Bessel Functions
19 Cylindrical Conductors
20 Spherical Harmonics
21 Coulomb's Potential
22 Multipoles
23 Conducting and Dielectric Spheres
24 Dielectrics and Conductors
25 Modes and Variations
26 Magnetostatics
27 Macroscopic Current Distributions
28 Magnetic Multipoles
29 Magnetic Scalar Potential
30 Magnetic Charge II
31 Retarded Green's Function
32 Radiation-Field Point of View
33 Radiation-Source Point of View
34 Models of Antennas
35 Spectral Distribution of Radiation
36 Power Spectrum and Cerenkov Radiation
37 Constant Acceleration and Impulse
38 Synchrotron Radiation I
39 Synchrotron Radiation II-Polarization
40 Synchrotron Radiation III-High Energies
41 Propagation in a Dielectric Medium
42 Reflection by an Imperfect Conductor
43 Cylindrical Coordinates
44 Waveguides
45 Scattering by Small Obstacles
46 Partial-Wave Analysis of Scattering
4 7 Diffraction I
48 Diffraction II
49 Babinet's Principle
50 General Scattering
51 Dispersion Relations for the Susceptibility
52 Charged Particle Energy Loss
A Units
B Bibliography
Index
Reader's Guide
1 Maxwell's Equations
2 Magnetic Charge I
3 Conservation Laws
4 Macroscopic Electrodynamics
5 Simple Model for Constitutive Relations
6 Magnetic Properties of Matter
7 Macroscopic Energy and Momentum
8 Review of Action Principles
9 Action Principle for Electrodynamics
10 Einsteinian Relativity
11 Stationary Principles for Electrostatics
12 Introduction to Green's Functions
13 Electrostatics in Free Space
14 Semi-Infinite Dielectric
15 Application of Green's Function
16 Bessel Functions
17 Parallel Conducting Plates
18 Modified Bessel Functions
19 Cylindrical Conductors
20 Spherical Harmonics
21 Coulomb's Potential
22 Multipoles
23 Conducting and Dielectric Spheres
24 Dielectrics and Conductors
25 Modes and Variations
26 Magnetostatics
27 Macroscopic Current Distributions
28 Magnetic Multipoles
29 Magnetic Scalar Potential
30 Magnetic Charge II
31 Retarded Green's Function
32 Radiation-Field Point of View
33 Radiation-Source Point of View
34 Models of Antennas
35 Spectral Distribution of Radiation
36 Power Spectrum and Cerenkov Radiation
37 Constant Acceleration and Impulse
38 Synchrotron Radiation I
39 Synchrotron Radiation II-Polarization
40 Synchrotron Radiation III-High Energies
41 Propagation in a Dielectric Medium
42 Reflection by an Imperfect Conductor
43 Cylindrical Coordinates
44 Waveguides
45 Scattering by Small Obstacles
46 Partial-Wave Analysis of Scattering
4 7 Diffraction I
48 Diffraction II
49 Babinet's Principle
50 General Scattering
51 Dispersion Relations for the Susceptibility
52 Charged Particle Energy Loss
A Units
B Bibliography
Index