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Electricity and Magnetism: New Formulation by Introduction of Superconductivity Second Edition 2021 [Minkštas viršelis]

  • Formatas: Paperback / softback, 438 pages, aukštis x plotis: 235x155 mm, weight: 765 g, 9 Illustrations, color; 311 Illustrations, black and white; XVI, 438 p. 320 illus., 9 illus. in color., 1 Paperback / softback
  • Serija: Undergraduate Lecture Notes in Physics
  • Išleidimo metai: 22-Sep-2021
  • Leidėjas: Springer Nature Switzerland AG
  • ISBN-10: 3030821498
  • ISBN-13: 9783030821494
Kitos knygos pagal šią temą:
Electricity and Magnetism: New Formulation by Introduction of Superconductivity Second Edition 2021Didesnis paveikslėlis
  • Formatas: Paperback / softback, 438 pages, aukštis x plotis: 235x155 mm, weight: 765 g, 9 Illustrations, color; 311 Illustrations, black and white; XVI, 438 p. 320 illus., 9 illus. in color., 1 Paperback / softback
  • Serija: Undergraduate Lecture Notes in Physics
  • Išleidimo metai: 22-Sep-2021
  • Leidėjas: Springer Nature Switzerland AG
  • ISBN-10: 3030821498
  • ISBN-13: 9783030821494
Kitos knygos pagal šią temą:
Pastovi nuoroda: https://www.kriso.lt/db/9783030821494.html
This book is a very comprehensive textbook covering in great depth all the electricity and magnetism. The 2nd edition includes new and revised figures and exercises in many of the chapters, and the number of problems and exercises for the student is increased.

In the 1st edition, emphasis much was made of superconductivity, and this methodology will be continued in the new edition by strengthening of the E-B analogy. Many of the new exercises and problems are associated with the E-B analogy, which enables those teaching from the book to select suitable teaching methods depending on the students ability and courses taken, whether physics, astrophysics, or engineering.



Changes in the chapters include a detailed discussion of the equivector-potential surface and its correspondence between electricity and magnetism. The shortcomings of using the magnetic scalar potential are also explained. The zero resistivity in a magnetic material showing perfect diamagnetism can be easily proved.



This textbook is an ideal text for students, who are competent in calculus and are taking physics, astrophysics, or engineering at degree level. It is also useful as a reference book for the professional scientist.

Recenzijos

The purpose of this book is to provide an introduction to electromagnetism which is oriented toward superconductivity applications. It is this practical aspect that distinguishes this book from others. The volume also provides the reader with a set of exercises and homework problems. The target audience for this book is undergraduate and graduate students in physics and engineering. (Christian Brosseau, optica-opn.org, April 21, 2022)

Part I Static Electric Phenomena
1 Electrostatic Field
3(34)
1.1 Electric Charge in Vacuum
3(2)
1.2 Coulomb's Law
5(3)
1.3 Electric Field
8(4)
1.4 Gauss' Law
12(6)
1.5 Electric Potential
18(7)
1.6 Electric Dipole
25(12)
Exercises
32(5)
2 Conductors
37(28)
2.1 Electric Properties of Conductors
37(11)
2.2 Special Solution Method for Electrostatic Field
48(7)
2.3 Electrostatic Induction
55(10)
Exercises
60(5)
3 Conductor Systems in Vacuum
65(24)
3.1 Coefficients in Conductor System
65(6)
3.2 Capacitor
71(6)
3.3 Electrostatic Energy
77(6)
3.4 Electrostatic Force
83(6)
Exercises
86(3)
4 Dielectric Materials
89(30)
4.1 Electric Polarization
89(8)
4.2 Electric Flux Density
97(4)
4.3 Boundary Conditions
101(10)
4.4 Electrostatic Energy in Dielectric Materials
111(8)
Exercises
115(4)
5 Steady Current
119(28)
5.1 Current
119(2)
5.2 Ohm's Law
121(3)
5.3 Microscopic Investigation of Electric Resistance
124(3)
5.4 Fundamental Equations for Steady Electric Current
127(8)
5.5 Electromotive Force
135(2)
5.6 Kirchhoff's Law
137(10)
Exercises
140(7)
Part II Static Magnetic Phenomena
6 Current and Magnetic Flux Density
147(40)
6.1 Magnetic Flux Density by Current
147(2)
6.2 The Biot--Savart Law
149(5)
6.3 Force on Current
154(4)
6.4 Magnetic Flux Lines
158(2)
6.5 Ampere's Law
160(5)
6.6 Vector Potential
165(5)
6.7 Small Closed Current
170(3)
6.8 Magnetic Charge
173(5)
6.9 Equivector Potential Surface
178(9)
Exercises
182(5)
7 Superconductors
187(34)
7.1 Magnetic Properties of Superconductors
187(13)
7.2 Special Solution Method for Magnetic Flux Density
200(5)
7.3 Meissner State
205(7)
7.4 Prediction of Superconductivity
212(9)
Exercises
216(5)
8 Current Systems
221(30)
8.1 Inductance
221(8)
8.2 Coils
229(6)
8.3 Magnetic Energy
235(7)
8.4 Magnetic Force
242(9)
Exercises
245(6)
9 Magnetic Materials
251(38)
9.1 Magnetization
251(9)
9.2 Magnetic Field
260(4)
9.3 Boundary Conditions
264(12)
9.4 Magnetic Energy in Magnetic Material
276(3)
9.5 Analogy Between Electric and Magnetic Phenomena
279(10)
Exercises
283(6)
Part III Time-Dependent Electromagnetic Phenomena
10 Electromagnetic Induction
289(28)
10.1 Induction Law
289(12)
10.2 Potential
301(1)
10.3 Boundary Conditions
302(1)
10.4 Magnetic Energy
303(3)
10.5 Skin Effect
306(11)
Exercises
313(4)
11 Displacement Current and Maxwell's Equations
317(22)
11.1 Displacement Current
317(4)
11.2 Maxwell's Equations
321(3)
11.3 Boundary Conditions
324(1)
11.4 Electromagnetic Potential
325(1)
11.5 The Poynting Vector
326(13)
Exercises
334(5)
12 Electromagnetic Wave
339(24)
12.1 Planar Electromagnetic Wave
339(4)
12.2 Reflection and Refraction of the Planar Electromagnetic Wave
343(6)
12.3 Energy of the Electromagnetic Wave
349(2)
12.4 Wave Guide
351(6)
12.5 Spherical Wave
357(1)
12.6 Retarded Potential
358(5)
Exercises
361(2)
Appendix A
363(118)
Answers to Exercises
397(84)
Literature 481(2)
Index 483
Prof. Dr. Teruo Matsushita has studied flux pinning and related electromagnetic phenomena in superconductors for 48 years. The first research field includes theoretical calculation of elementary pinning force of specific pinning centers and estimation of the pinning force density as a function of the elementary pinning force and number density. In the latter research field he establish the critical state theory that supports the well-known critical state model by using the first principles of minimizing the free energy in the reversible state followed by development to the irreversible state. The theoretical analyses of the longitudinal field problem and the effect of flux creep in high-temperature superconductors are also included in the latter category.  He is a member of The Institute of Electrical Engineers of Japan, The Japan Society of Applied Physics, Cryogenics and Superconductivity of Japan, and Institute of Physics (UK).