Student's Guide to Maxwell's Equations

Name: Student's Guide to Maxwell's Equations
Price: 10.87 USD
Availability: InStock
ISBN: 9780521701471

ISBN-10: 0521701473

ISBN-13: 9780521701471

Edition: 2007

Authors: Daniel Fleisch

List price: $33.99

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Description:

Gauss's law for electric fields, Gauss's law for magnetic fields, Faraday's law, and the Ampere-Maxwell law are four of the most influential equations in science. In this guide for students, each equation is the subject of an entire chapter, with detailed, plain-language explanations of the physical meaning of each symbol in the equation, for both the integral and differential forms. The final chapter shows how Maxwell's equations may be combined to produce the wave equation, the basis for the electromagnetic theory of light. This book is a wonderful resource for undergraduate and graduate courses in electromagnetism and electromagnetics. A website hosted by the author at…

Book details

List price: $33.99
Copyright year: 2007
Publisher: Cambridge University Press
Publication date: 1/10/2008
Binding: Paperback
Pages: 142
Size: 5.98" wide x 9.02" long x 0.31" tall
Weight: 0.726
Language: English



Preface


Acknowledgments



Gauss's law for electric fields



The integral form of Gauss's law


The electric field


The dot product


The unit normal vector


The component of E normal to a surface


The surface integral


The flux of a vector field


The electric flux through a closed surface


The enclosed charge


The permittivity of free space


Applying Gauss's law (integral form)



The differential form of Gauss's law


Nabla - the del operator


Del dot - the divergence


The divergence of the electric field


Applying Gauss's law (differential form)



Gauss's law for magnetic fields



The integral form of Gauss's law


The magnetic field


The magnetic flux through a closed surface


Applying Gauss's law (integral form)



The differential form of Gauss's law


The divergence of the magnetic field


Applying Gauss's law (differential form)



Faraday's law



The integral form of Faraday's law


The induced electric field


The line integral


The path integral of a vector field


The electric field circulation


The rate of change of flux


Lenz's law


Applying Faraday's law (integral form)



The differential form of Faraday's law


Del cross - the curl


The curl of the electric field


Applying Faraday's law (differential form)



The Ampere-Maxwell law



The integral form of the Ampere-Maxwell law


The magnetic field circulation


The permeability of free space


The enclosed electric current


The rate of change of flux


Applying the Ampere-Maxwell law (integral form)



The differential form of the Ampere-Maxwell law


The curl of the magnetic field


The electric current density


The displacement current density


Applying the Ampere-Maxwell law (differential form)



From Maxwell's Equations to the wave equation


The divergence theorem


Stokes' theorem


The gradient


Some useful identities


The wave equation



Maxwell's Equations in matter


Further reading


Index