Classical electromagnetism / (Record no. 1415)

MARC details
000 -LEADER
fixed length control field 14560cam a22002294a 4500
001 - CONTROL NUMBER
control field 13817765
003 - CONTROL NUMBER IDENTIFIER
control field OSt
005 - DATE AND TIME OF LATEST TRANSACTION
control field 20131004145241.0
008 - FIXED-LENGTH DATA ELEMENTS--GENERAL INFORMATION
fixed length control field 041217s2005 caua b 001 0 eng
010 ## - LIBRARY OF CONGRESS CONTROL NUMBER
LC control number 2004030193
020 ## - INTERNATIONAL STANDARD BOOK NUMBER
International Standard Book Number 9788131709740 (pbk)
040 ## - CATALOGING SOURCE
Transcribing agency NCL
082 00 - DEWEY DECIMAL CLASSIFICATION NUMBER
Classification number 537
Item number FRA-C 2012 2005
100 1# - MAIN ENTRY--PERSONAL NAME
Personal name Franklin, Jerrold.
245 10 - TITLE STATEMENT
Title Classical electromagnetism /
Statement of responsibility, etc. by Jerrold Franklin.
260 ## - PUBLICATION, DISTRIBUTION, ETC. (IMPRINT)
Place of publication, distribution, etc. San Francisco :
Name of publisher, distributor, etc. Pearson Addison-Wesley,
Date of publication, distribution, etc. c2012.
300 ## - PHYSICAL DESCRIPTION
Extent xiv, 469 p. :
Other physical details ill. ;
Dimensions 25 cm.
504 ## - BIBLIOGRAPHY, ETC. NOTE
Bibliography, etc Includes bibliographical references (p. 459) and index.
505 ## - FORMATTED CONTENTS NOTE
Formatted contents note *Contents<br/>ContentsContents<br/>chapter1Foundations of Electrostatics1<br/>section1.1Coulomb's Law1<br/>section1.2The Electric Field4<br/>section1.3Electric Potential6<br/>subsection1.3.1Potential Gradient9<br/>section1.4Gauss's Law12<br/>subsection1.4.1Examples of Gauss's Law14<br/>subsubsectionPoint Charge14<br/>subsection1.4.2Spherically Symmetric Charge (and Mass)Distributions16<br/>subsubsectionLine Charge17<br/>subsubsectionInfinite Plane18<br/>section1.5The Variation of E19<br/>subsection1.5.1Divergence20<br/>subsection1.5.2Dirac Delta Function23<br/>subsection1.5.3Curl25<br/>section1.6Summary of Vector Calculus29<br/>subsection1.6.1Operation by 30<br/>subsection1.6.2Integral Theorems32<br/>section1.7Problems34<br/>chapter2Further Development of Electrostatics37<br/>section2.1Conductors37<br/>section2.2Electrostatic Energy40<br/>section2.3Electric Dipoles46<br/>subsection2.3.1Fields Due to Dipoles46<br/>subsection2.3.2Forces and Torques on Dipoles48<br/>subsection2.3.3Dipole Singularity at 51<br/>section2.4Electric Quadrupole Moment53<br/>subsection2.4.1Dyadics54<br/>subsection2.4.2Quadrupole dyadic55<br/>subsection2.4.3Multipole Expansion60<br/>section2.5Problems60<br/>chapter3Methods of Solution in Electrostatics63<br/>section3.1Differential Form of Electrostatics63<br/>subsection3.1.1Uniqueness Theorem64<br/>paragraphDirichlet Boundary Condition:66<br/>paragraphNeumann Boundary Condition:66<br/>paragraphUniqueness Theorem of Electrostatics:66<br/>paragraphUniqueness Theorem of Electrostatics in the Presence of Conductors:67<br/>paragraphUniqueness Theorem for the Electrostatic Potential:67<br/>section3.2Images68<br/>subsection3.2.1Infinite Grounded Plane68<br/>subsection3.2.2Conducting Sphere70<br/>section3.3Separation of Variables for Laplace's Equation73<br/>subsection3.3.1Cartesian Coordinates73<br/>subsection3.3.2Fourier Series76<br/>subsection3.3.3Fourier Sine Integrals79<br/>section3.4Surface Green's Function82<br/>section3.5Problems86<br/>chapter4Spherical and Cylindrical Coordinates89<br/>section4.1General Orthogonal Coordinate Systems89<br/>section4.2Spherical Coordinates91<br/>subsection4.2.1Separation of Variables in Spherical Coordinates93<br/>subsection4.2.2Azimuthal Symmetry, Legendre Polynomials94<br/>paragraphNormalization97<br/>paragraphOrthogonality97<br/>paragraphGenerating Function99<br/>paragraphRecursion Relation100<br/>paragraph, , 100<br/>subsection4.2.3Boundary Value Problems with AzimuthalSymmetry100<br/>subsubsectionPotential Outside a Sphere101<br/>subsection4.2.4Multipole Expansion104<br/>subsubsectionUniformly Charged Needle105<br/>subsubsectionMutipole Expansion for a Point Charge, Derivation of the Generating Function for Legendre Polynomials107<br/>subsubsectionPoint Charge and Grounded Sphere108<br/>subsubsectionMultipole Moment by Integration108<br/>subsection4.2.5Spherical Harmonics109<br/>subsubsectionPotential Outside a Sphere112<br/>subsubsectionMultipole Moments112<br/>subsubsectionRotation of Axes113<br/>subsubsectionAddition Theorem114<br/>subsubsectionMultipole Moment by Integration115<br/>section4.3Cylindrical Coordinates117<br/>subsection4.3.1Separation of Variables in Cylindrical Coordinates118<br/>subsection4.3.2Two-Dimensional Cases (Polar Coordinates)119<br/>subsubsectionPotential Inside a Cylinder120<br/>subsubsectionFourier Series120<br/>subsubsectionIntersecting Grounded Planes121<br/>subsection4.3.3Three-Dimensional Cases, Bessel Functions123<br/>subsubsectionBessel Functions123<br/>paragraphRecursion Relation126<br/>paragraphDerivative Recursion Relation126<br/>paragraphAsymptotic Forms126<br/>subsubsectionPotential Inside a Cylinder127<br/>subsubsectionModified Bessel Functions130<br/>section4.4Problems132<br/>chapter5Green's Functions135<br/>section5.1Application of Green's Second Theorem135<br/>section5.2Surface Boundary Conditions135<br/>section5.3Green's Function Solution of Poisson's Equation136<br/>section5.4Surface Green's Function137<br/>section5.5Symmetry of the Green's Function137<br/>section5.6Green's Reciprocity Theorem138<br/>section5.7Green's Functions for Specific Cases140<br/>subsubsectionPlane Surface140<br/>subsubsectionSphere140<br/>section5.8Constructing Green's Functions141<br/>subsection5.8.1Construction of the Green's Function fromEigenfunctions141<br/>subsection5.8.2Reduction to a One-Dimensional Green's Function142<br/>subsubsectionRectangular Coordinates142<br/>subsubsectionSpherical Coordinates146<br/>section5.9Problems147<br/>chapter6Electrostatics in Matter149<br/>section6.1Polarization149<br/>section6.2The Displacement Vector D150<br/>section6.3Uniqueness Theorem with Polarization153<br/>section6.4Boundary Value Problems with Polarization154<br/>subsection6.4.1Boundary Conditions on D, E, and 154<br/>subsection6.4.2Needle or Lamina156<br/>subsection6.4.3Capacitance157<br/>subsection6.4.4Images158<br/>subsection6.4.5Dielectric Sphere in a Uniform Electric Field160<br/>subsection6.4.6Dielectric Sphere and Point Charge161<br/>section6.5Induced Dipole--Dipole Force, the Van der Waals Force163<br/>section6.6Molecular Polarizability164<br/>subsection6.6.1Microscopic Electric Field164<br/>subsection6.6.2Clausius--Mossotti Relation166<br/>subsection6.6.3Models for Molecular Polarization167<br/>section6.7Electrostatic Energy in Dielectrics169<br/>section6.8Forces on Dielectrics170<br/>section6.9Steady State Currents174<br/>subsection6.9.1Current Density and Continuity Equation174<br/>subsection6.9.2Ohm's Law175<br/>subsection6.9.3Relaxation Constant176<br/>subsection6.9.4Effective Resistance177<br/>section6.10Problems179<br/>chapter7Magnetostatics181<br/>section7.1Magnetic Forces Between Electric Currents181<br/>section7.2Units of Electricity and Magnetism183<br/>section7.3The Magnetic Field B186<br/>section7.4Applications of the Biot--Savart Law187<br/>section7.5Magnetic Effects on Charged Particles190<br/>section7.6Magnetic Effects of Current Densities193<br/>subsection7.6.1Volume Current Density j193<br/>subsection7.6.2Surface Current Density K194<br/>subsection7.6.3Magnetic Effects of Moving Charges?195<br/>section7.7Differential Form of Magnetostatics196<br/>section7.8The Vector Potential A198<br/>subsection7.8.1Gauge Transformation198<br/>subsection7.8.2Poisson's Equation for A199<br/>section7.9Ampere's Circuital Law200<br/>section7.10Magnetic Scalar Potential203<br/>subsection7.10.1Magnetic Field of a Current Loop205<br/>section7.11Magnetic Dipole Moment209<br/>subsection7.11.1Magnetic Multipole Expansion209<br/>subsection7.11.2Magnetic Dipole Scalar Potential of a Current Loop209<br/>subsection7.11.3Magnetic Dipole Vector Potential of a Current Loop210<br/>subsection7.11.4Magnetic Dipole Moment of a Current Density212<br/>subsection7.11.5Gyromagnetic Ratio213<br/>subsection7.11.6The Zeeman Effect214<br/>subsection7.11.7Magnetic Dipole Force, Torque, and Energy215<br/>subsection7.11.8Fermi--Breit Interaction between Magnetic Dipoles218<br/>section7.12Problems219<br/>chapter8Magnetization and Ferromagnetism223<br/>section8.1Magnetic Field Including Magnetization223<br/>section8.2The H Field, Susceptibility, and Permeability225<br/>section8.3Comparison of Magnetostatics and Electrostatics228<br/>section8.4Ferromagnetism229<br/>section8.5Hysteresis229<br/>section8.6Permanent Magnetism231<br/>section8.7Magnetization of a Ferromagnetic Sphere232<br/>section8.8The Use of the H Field for a Permanent Magnet233<br/>section8.9Bar Magnet234<br/>section8.10Magnetic Images238<br/>section8.11Problems239<br/>chapter9Time Varying Fields, Maxwell's Equations241<br/>section9.1Faraday's Law241<br/>section9.2Inductance245<br/>section9.3Displacement Current, Maxwell's Equations247<br/>section9.4Electromagnetic Energy248<br/>subsection9.4.1Potential Energy in Matter249<br/>section9.5Magnetic Energy251<br/>section9.6Electromagnetic Momentum, Maxwell Stress Tensor253<br/>subsection9.6.1Momentum in the Polarization and MagnetizationFields256<br/>section9.7Application of the Stress Tensor258<br/>section9.8Magnetic Monopoles259<br/>subsection9.8.1Dirac Charge Quantization260<br/>section9.9Problems262<br/>chapter10Electromagnetic Plane Waves265<br/>section10.1Electromagnetic Waves from Maxwell's Equations265<br/>section10.2Energy and Momentum in an Electromagnetic Wave267<br/>subsection10.2.1Radiation Pressure269<br/>section10.3Polarization270<br/>subsection10.3.1Polarized Light270<br/>subsection10.3.2Circular Basis for Polarization271<br/>subsection10.3.3Birefringence273<br/>subsection10.3.4Unpolarized Light275<br/>section10.4Reflection and Refraction at a Planar Interface276<br/>subsection10.4.1Snell's Law277<br/>subsection10.4.2Perpendicular Polarization278<br/>subsection10.4.3Parallel Polarization280<br/>subsection10.4.4Normal Incidence281<br/>subsection10.4.5Polarization by Reflection281<br/>subsection10.4.6Total Internal Reflection283<br/>subsection10.4.7Nonreflective Coating285<br/>section10.5Problems287<br/>chapter11Electromagnetic Waves in Matter290<br/>section11.1Electromagnetic Waves in a Conducting Medium290<br/>subsection11.1.1Poor Conductor292<br/>subsection11.1.2Good Conductor293<br/>section11.2Electromagnetic Wave at the Interface of a Conductor293<br/>subsection11.2.1Perfect Conductor293<br/>subsection11.2.2Radiation Pressure294<br/>subsection11.2.3Interface with a Good Conductor295<br/>subsubsectionEnergy Absorption at the Interface297<br/>subsubsectionEffective Surface Current298<br/>section11.3Frequency Dependence of Permittivity298<br/>subsection11.3.1Molecular Model for Permittivity298<br/>subsection11.3.2Dispersion and Absorption299<br/>subsection11.3.3Conduction Electrons300<br/>section11.4Causal Relation between D and E301<br/>section11.5Wave Packets304<br/>subsection11.5.1Natural Line Width306<br/>section11.6Wave Propagation in a Dispersive Medium307<br/>subsection11.6.1Group Velocity and Phase Velocity307<br/>subsection11.6.2Spread of a Wave Packet309<br/>subsection11.6.3No Electromagnetic Wave Travels Faster Than 310<br/>section11.7Problems313<br/>chapter12Wave Guides and Cavities315<br/>section12.1Cylindrical Wave Guides315<br/>subsection12.1.1Phase and Group Velocities in a Wave Guide316<br/>section12.2Eigenmodes in a Waveguide317<br/>subsection12.2.1TEM Waves318<br/>subsubsectionCoaxial Wave Guide319<br/>subsubsectionParallel-Wire Wave Guide319<br/>subsection12.2.2TM Waves320<br/>subsection12.2.3TE Waves320<br/>subsection12.2.4Summary of TM and TE Modes321<br/>subsection12.2.5Rectangular Wave Guides322<br/>subsubsectionTM Modes:322<br/>subsubsectionTE Modes:323<br/>subsection12.2.6Circular Wave Guides324<br/>section12.3Power Transmission and Attenuation in Wave Guides325<br/>subsection12.3.1Power Transmitted325<br/>subsection12.3.2Losses and Attenuation327<br/>section12.4Cylindrical Cavities328<br/>subsection12.4.1Resonant Modes of a Cavity328<br/>subsection12.4.2Rectangular Cavity330<br/>subsection12.4.3Circular Cylindrical Cavity330<br/>subsection12.4.4Electromagnetic Energy in a Cavity331<br/>subsection12.4.5Power Loss, Quality Factor333<br/>section12.5Problems335<br/>chapter13Electromagnetic Radiation and Scattering337<br/>section13.1Wave Equation with Sources337<br/>section13.2The Lorentz Gauge338<br/>section13.3Retarded Solution of the Wave Equation339<br/>section13.4Radiation Solution of the Wave Equation342<br/>section13.5Center Fed Linear Antenna345<br/>section13.6Electric Dipole Radiation348<br/>section13.7Radiation by Atoms351<br/>section13.8Larmor Formula for Radiation by an Accelerating Charge352<br/>section13.9Magnetic Dipole Radiation355<br/>section13.10Electric Quadrupole Radiation356<br/>section13.11Scattering of Electromagnetic Radiation360<br/>subsection13.11.1Electric Dipole Scattering360<br/>subsection13.11.2Scattering by a Conducting Sphere, Magnetic Dipole Scattering363<br/>section13.12Problems365<br/>chapter14Special Relativity368<br/>section14.1The Need for Relativity368<br/>section14.2Mathematical Basis of Special Relativity, the Lorentz Transformation371<br/>section14.3Spatial and Temporal Consequences of the Lorentz Transformation374<br/>subsection14.3.1Relativistic Addition of Velocities374<br/>subsection14.3.2Lorentz Contraction376<br/>subsection14.3.3Time Dilation377<br/>section14.4Mathematics of the Lorentz Transformation378<br/>subsection14.4.1Three-Dimensional Rotations379<br/>subsection14.4.2Lorentz Four-Vectors and Scalar Invariants382<br/>section14.5Relativistic Space-Time386<br/>subsection14.5.1The Light Cone387<br/>subsection14.5.2Proper Time388<br/>section14.6Relativistic Kinematics390<br/>subsection14.6.1Four-Velocity390<br/>subsection14.6.2Energy-Momentum Four-Vector391<br/>subsection14.6.3392<br/>section14.7Doppler Shift and Stellar Aberration393<br/>section14.8Natural Relativistic Units, No More c395<br/>section14.9Relativistic ``Center of Mass''396<br/>section14.10Covariant Electromagnetism398<br/>subsection14.10.1Charge-Current Four-Vector 398<br/>subsection14.10.2Lorentz Invariance of Charge399<br/>subsection14.10.3The Four-Potential 400<br/>subsection14.10.4The Electromagnetic Field Tensor 401<br/>section14.11Problems404<br/>chapter15The Electrodynamics of Moving Bodies407<br/>section15.1Relativistic Electrodynamics407<br/>subsection15.1.1Covariant Extension of 407<br/>subsection15.1.2Motion in a Magnetic Field408<br/>subsection15.1.3Linear Accelerator409<br/>section15.2Lagrange's and Hamilton's Equations for Electrodynamics410<br/>subsection15.2.1Nonrelativistic Lagrangian410<br/>subsection15.2.2Relativistic Lagrangian412<br/>subsection15.2.3Hamiltonian for Electrodynamics414<br/>section15.3Fields of a Charge Moving with Constant Velocity415<br/>subsection15.3.1Energy Loss of a Moving Charge417<br/>subsection15.3.2Interaction between Moving Charges419<br/>section15.4Electromagnetic Fields of a Moving Charge421<br/>subsection15.4.1Covariant Solution of the Wave Equation421<br/>subsection15.4.2Lienard--Wiechert Potentials and Fields of a Moving Charge424<br/>subsection15.4.3Constant Velocity Fields427<br/>section15.5Electromagnetic Radiation by a Moving Charge428<br/>subsection15.5.1Radiation with Acceleration Parallel to Velocity429<br/>subsection15.5.2Radiation with Acceleration Perpendicular to Velocity431<br/>subsection15.5.3Radiation from a Circular Orbit433<br/>subsection15.5.4Relativistic Larmor formula436<br/>section15.6Problems437<br/>chapter16Classical Electromagnetism in a Quantum World439<br/>section16.1Looking Back439<br/>section16.2Electromagnetism as a Gauge Theory441<br/>section16.3Local Gauge Invariance as the Grand Unifier of Interactions444<br/>section16.4Classical Electromagnetism and Quantum Electrodynamics446<br/>section16.5Natural Units448<br/>section16.6451<br/>chapterAConversion of Units457<br/>chapterBDerivatives of the Retarded Time459<br/>chapterRecommended Reading461<br/>chapterIndex463
650 #0 - SUBJECT ADDED ENTRY--TOPICAL TERM
Topical term or geographic name as entry element Electromagnetism
Form subdivision Textbooks.
942 ## - ADDED ENTRY ELEMENTS (KOHA)
Source of classification or shelving scheme
Koha item type Books
Holdings
Withdrawn status Lost status Source of classification or shelving scheme Damaged status Not for loan Home library Current library Shelving location Date acquired Source of acquisition Total Checkouts Full call number Barcode Date last seen Date checked out Price effective from Koha item type
          Namal Library Namal Library Physics 10/01/2013 Old Books 1 537 FRA-C 2012 2005 0002005 03/27/2015 02/25/2015 10/01/2013 Books