Classical electromagnetism / (Record no. 1415)
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000 -LEADER | |
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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 |
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 |
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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 |