3.8 DIPOLE DISTRIBUTIONS-INTERIOR FIELDSPROBLEMS; REFERENCES; 4 - BOUNDARY VALUE PROBLEMS WITH CONDUCTORS; 4.1 THE PHYSICS OF CONDUCTORS IN FIELDS; 4.2 HOMOGENEOUS AND INHOMOGENEOUS PROBLEMS; 4.3 A UNIQUENESS THEOREM; 4.4 METHOD OF IMAGES; 4.5 LAPLACE'S EQUATION AND SUPERPOSITION OF ELEMENTARY SOLUTIONS; 4.6 COMPOSITE PROBLEMS; 4.7 INTEGRAL EQUATIONS; PROBLEMS; REFERENCES; 5 - GENERAL BOUNDARY VALUE PROBLEMS; 5.1 DIRICHLET AND NEUMANN PROBLEMS; 5.2 SUPERPOSITION OF ELEMENTARY SOLUTIONS; 5.3 GREEN'S THEOREM AND AN INTEGRAL IDENTITY FOR THE POTENTIAL.

5.4 A GENERALIZED INTEGRAL IDENTITY AND GREEN FUNCTIONS5.5 APPLICATION OF GREEN FUNCTIONS; 5.6 GENERAL PROPERTIES OF GREEN FUNCTIONS; PROBLEMS; REFERENCES; 6 - DIELECTRICS; 6.1 INTRODUCTION; 6.2 POLARIZATION CHARGE AND THE AVERAGE INTERNAL FIELD; 6.3 THE RELATION OF POLARIZATION TO THE APPLIED FIELD; 6.4 CAPACITORS AND THE DIELECTRIC CONSTANT; 6.5 BOUNDARY VALUE PROBLEMS WITH DIELECTRICS; 6.6 MACROSCOPIC AND MICROSCOPIC PROPERTIES; PROBLEMS; REFERENCES; 7 - THE MAGNETOSTATIC FIELD; 7.1 CURRENT AND RELATED CONCEPTS; 7.2 FORCES BETWEEN CONDUCTORS AND THE MAGNETOSTATIC FIELD B.

7.3 DIFFERENTIAL AND INTEGRAL PROPERTIES OF B7.4 THE MAGNETIC SCALAR POTENTIAL; 7.5 THE VECTOR POTENTIAL; PROBLEMS; REFERENCE; 8 - THE SUMMATION PROBLEM FOR STATIONARY CURRENTS; 8.1 INTRODUCTION; 8.2 INTEGRAL MAGNETIC SCALAR POTENTIAL; 8.3 DIFFERENTIAL MAGNETIC SCALAR POTENTIAL; 8.4 THE VECTOR POTENTIAL AND A MULTIPOLE EXPANSION; 8.5 EXTERNAL FIELD OF DIPOLAR MAGNETIC MATTER; PROBLEMS; REFERENCES; 9 - MAGNETIC MATERIALS AND BOUNDARY VALUE PROBLEMS; 9.1 INTRODUCTION; 9.2 AN AVERAGE INTERNAL FIELD; 9.3 A POSTULATE RELATING MEAN MAGNETIZATION AND THE APPLIED FIELD.

9.4 THEORY OF PERMEABLE MATTER IN AN APPLIED FIELD9.5 THE VECTOR H; 9.6 A BOUNDARY VALUE PROBLEM; PROBLEMS; REFERENCES; 10 - FORCE AND ENERGY IN STATIC FIELDS; 10.1 ENERGY OF ASSEMBLAGE OF CHARGE DISTRIBUTION; 10.2 ENERGY OF FORMATION OF CURRENT DISTRIBUTION; 10.3 RIGID CHARGE DISTRIBUTION IN APPLIED ELECTRIC FIELD; 10.4 RIGID CURRENT DISTRIBUTION IN APPLIED MAGNETIC FIELD; 10.5 FORCE ON CONDUCTORS; 10.6 DIELECTRIC MATTER IN APPLIED ELECTRIC FIELD; 10.7 PERMEABLE MATTER IN APPLIED MAGNETIC FIELD; PROBLEMS; REFERENCES; 11 - TIME-VARYING FIELDS; 11.1 INTRODUCTION.

11.2 FARADAY'S LAW OF INDUCTION.

This excellent text covers a year's course in advanced theoretical electromagnetism, first introducing theory, then its application. Topics include vectors D and H inside matter, conservation laws for energy, momentum, invariance, form invariance, covariance in special relativity, and more.