Electricity and Magnetism, Edition Third [3rd Ed] (Solutions) (Instructor Solution Manual)

Contents
Preface to the third edition of Volume 2
Preface to the second edition of Volume 2
Preface to the first edition of Volume 2
CHAPTER 1 ELECTROSTATICS: CHARGES AND FIELDS
	1.1 Electric charge
	1.2 Conservation of charge
	1.3 Quantization of charge
	1.4 Coulomb’s law
	1.5 Energy of a system of charges
	1.6 Electrical energy in a crystal lattice
	1.7 The electric field
	1.8 Charge distributions
	1.9 Flux
	1.10 Gauss’s law
	1.11 Field of a spherical charge distribution
	1.12 Field of a line charge
	1.13 Field of an infinite flat sheet of charge
	1.14 The force on a layer of charge
	1.15 Energy associated with the electric field
	1.16 Applications
	Chapter summary
	Problems
	Exercises
CHAPTER 2 THE ELECTRIC POTENTIAL
	2.1 Line integral of the electric field
	2.2 Potential difference and the potential function
	2.3 Gradient of a scalar function
	2.4 Derivation of the field from the potential
	2.5 Potential of a charge distribution
	2.6 Uniformly charged disk
	2.7 Dipoles
	2.8 Divergence of a vector function
	2.9 Gauss’s theorem and the differential form of Gauss’s law
	2.10 The divergence in Cartesian coordinates
	2.11 The Laplacian
	2.12 Laplace’s equation
	2.13 Distinguishing the physics from the mathematics
	2.14 The curl of a vector function
	2.15 Stokes’ theorem
	2.16 The curl in Cartesian coordinates
	2.17 The physical meaning of the curl
	2.18 Applications
	Chapter summary
	Problems
	Exercises
CHAPTER 3 ELECTRIC FIELDS AROUND CONDUCTORS
	3.1 Conductors and insulators
	3.2 Conductors in the electrostatic field
	3.3 The general electrostatic problem and the uniqueness theorem
	3.4 Image charges
	3.5 Capacitance and capacitors
	3.6 Potentials and charges on several conductors
	3.7 Energy stored in a capacitor
	3.8 Other views of the boundary-value problem
	3.9 Applications
	Chapter summary
	Problems
	Exercises
CHAPTER 4 ELECTRIC CURRENTS
	4.1 Electric current and current density
	4.2 Steady currents and charge conservation
	4.3 Electrical conductivity and Ohm’s law
	4.4 The physics of electrical conduction
	4.5 Conduction in metals
	4.6 Semiconductors
	4.7 Circuits and circuit elements
	4.8 Energy dissipation in current flow
	4.9 Electromotive force and the voltaic cell
	4.10 Networks with voltage sources
	4.11 Variable currents in capacitors and resistors
	4.12 Applications
	Chapter summary
	Problems
	Exercises
CHAPTER 5 THE FIELDS OF MOVING CHARGES
	5.1 From Oersted to Einstein
	5.2 Magnetic forces
	5.3 Measurement of charge in motion
	5.4 Invariance of charge
	5.5 Electric field measured in different frames of reference
	5.6 Field of a point charge moving with constant velocity
	5.7 Field of a charge that starts or stops
	5.8 Force on a moving charge
	5.9 Interaction between a moving charge and other moving charges
	Chapter summary
	Problems
	Exercises
CHAPTER 6 THE MAGNETIC FIELD
	6.1 Definition of the magnetic field
	6.2 Some properties of the magnetic field
	6.3 Vector potential
	6.4 Field of any current-carrying wire
	6.5 Fields of rings and coils
	6.6 Change in Bat a current sheet
	6.7 How the fields transform
	6.8 Rowland’s experiment
	6.9 Electrical conduction in a magnetic field: the Hall effect
	6.10 Applications
	Chapter summary
	Problems
	Exercises
CHAPTER 7 ELECTROMAGNETIC INDUCTION
	7.1 Faraday’s discovery
	7.2 Conducting rod moving through a uniform magnetic field
	7.3 Loop moving through a nonuniform magnetic field
	7.4 Stationary loop with the field source moving
	7.5 Universal law of induction
	7.6 Mutual inductance
	7.7 A reciprocity theorem
	7.8 Self-inductance
	7.9 Circuit containing self-inductance
	7.10 Energy stored in the magnetic field
	7.11 Applications
	Chapter summary
	Problems
	Exercises
CHAPTER 8 ALTERNATING-CURRENT CIRCUITS
	8.1 A resonant circuit
	8.2 Alternating current
	8.3 Complex exponential solutions
	8.4 Alternating-current networks
	8.5 Admittance and impedance
	8.6 Power and energy in alternating-current circuits
	8.7 Applications
	Chapter summary
	Problems
	Exercises
CHAPTER 9 MAXWELL’S EQUATIONS AND ELECTROMAGNETIC WAVES
	9.1 “Something is missing”
	9.2 The displacement current
	9.3 Maxwell’s equations
	9.4 An electromagnetic wave
	9.5 Other waveforms; superposition of waves
	9.6 Energy transport by electromagnetic waves
	9.7 How a wave looks in a different frame
	9.8 Applications
	Chapter summary
	Problems
	Exercises
CHAPTER 10 ELECTRIC FIELDS IN MATTER
	10.1 Dielectrics
	10.2 The moments of a charge distribution
	10.3 The potential and field of a dipole
	10.4 The torque and the force on a dipole in an external field
	10.5 Atomic and molecular dipoles; induced dipole moments
	10.6 Permanent dipole moments
	10.7 The electric field caused by polarized matter
	10.8 Another look at the capacitor
	10.9 The field of a polarized sphere
	10.10 A dielectric sphere in a uniform field
	10.11 The field of a charge in a dielectric medium, and Gauss’s law
	10.12 A microscopic view of the dielectric
	10.13 Polarization in changing fields
	10.14 The bound-charge current
	10.15 An electromagnetic wave in a dielectric
	10.16 Applications
	Chapter summary
	Problems
	Exercises
CHAPTER 11 MAGNETIC FIELDS IN MATTER
	11.1 How various substances respond to a magnetic field
	11.2 The absence of magnetic “charge”
	11.3 The field of a current loop
	11.4 The force on a dipole in an external field
	11.5 Electric currents in atoms
	11.6 Electron spin and magnetic moment
	11.7 Magnetic susceptibility
	11.8 The magnetic field caused by magnetized matter
	11.9 The field of a permanent magnet
	11.10 Free currents, and the field H
	11.11 Ferromagnetism
	11.12 Applications
	Chapter summary
	Problems
	Exercises
CHAPTER 12 SOLUTIONS TO THE PROBLEMS
	12.1 Chapter 1
	12.2 Chapter 2
	12.3 Chapter 3
	12.4 Chapter 4
	12.5 Chapter 5
	12.6 Chapter 6
	12.7 Chapter 7
	12.8 Chapter 8
	12.9 Chapter 9
	12.10 Chapter 10
	12.11 Chapter 11
Appendix A: Differences between SI and Gaussian units
Appendix B: SI units of common quantities
Appendix C: Unit conversions
Appendix D: SI and Gaussian formulas
Appendix E: Exact relations among SI and Gaussian units
Appendix F: Curvilinear coordinates
Appendix G: A short review of special relativity
Appendix H: Radiation by an accelerated charge
Appendix I: Superconductivity
Appendix J: Magnetic resonance
Appendix K: Helpful formulas/facts
References
Index