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Course in Classical Physics 3 Electromagnetism 1st ed. 2016 [Minkštas viršelis]

  • Formatas: Paperback / softback, 403 pages, aukštis x plotis: 235x155 mm, weight: 869 g, 2 Illustrations, color; 207 Illustrations, black and white; XX, 403 p. 209 illus., 2 illus. in color., 1 Paperback / softback
  • Serija: Undergraduate Lecture Notes in Physics
  • Išleidimo metai: 08-Aug-2016
  • Leidėjas: Springer International Publishing AG
  • ISBN-10: 3319408704
  • ISBN-13: 9783319408705
Kitos knygos pagal šią temą:
Course in Classical Physics 3 Electromagnetism 1st ed. 2016Didesnis paveikslėlis
  • Formatas: Paperback / softback, 403 pages, aukštis x plotis: 235x155 mm, weight: 869 g, 2 Illustrations, color; 207 Illustrations, black and white; XX, 403 p. 209 illus., 2 illus. in color., 1 Paperback / softback
  • Serija: Undergraduate Lecture Notes in Physics
  • Išleidimo metai: 08-Aug-2016
  • Leidėjas: Springer International Publishing AG
  • ISBN-10: 3319408704
  • ISBN-13: 9783319408705
Kitos knygos pagal šią temą:
Pastovi nuoroda: https://www.kriso.lt/db/9783319408705.html
Raktažodžiai:
Focusing on electromagnetism, this third volume of a four-volume textbook covers the electric field under static conditions, constant electric currents and their laws, the magnetic field in a vacuum, electromagnetic induction, magnetic energy under static conditions, the magnetic properties of matter, and the unified description of electromagnetic phenomena provided by Maxwells equations.

The four-volume textbook as a whole covers electromagnetism, mechanics, fluids and thermodynamics, and waves and light, and is designed to reflect the typical syllabus during the first two years of a calculus-based university physics program. 





Throughout all four volumes, particular attention is paid to in-depth clarification of conceptual aspects, and to this end the historical roots of the principal concepts are traced. Emphasis is also consistently placed on the experimental basis of the concepts, highlighting the experimental nature of physics. Whenever feasible at theelementary level, concepts relevant to more advanced courses in quantum mechanics and atomic, solid state, nuclear, and particle physics are included. 

The textbook offers an ideal resource for physics students, lecturers and, last but not least, all those seeking a deeper understanding of the experimental basics of physics. 

Recenzijos

The third volume of the course deals with classical electromagnetic phenomena. Alessandro Bettini has fulfilled the ambitious goal of writing a treatise that covers all of classical physics with a depth suitable for honor undergraduate courses. Bettinis books not only teach but inspire, and they will appeal to students and professors alike who feel that physics is truly rich of great ideas that deserve to be studied with devotion and love. (Giuseppe La Rocca, Il Nuovo Saggiatore, April, 2017)

1 Electrostatic Field in a Vacuum
1(60)
1.1 Electric Charge
2(5)
1.2 Coulomb's Law
7(6)
1.3 The Electrostatic Field
13(3)
1.4 Calculating Electric Fields
16(3)
1.5 Electrostatic Potential
19(3)
1.6 Generating Electrostatic Potential Differences
22(2)
1.7 Calculating Electrostatic Potentials
24(3)
1.8 Measuring the Elementary Charge. Millikan's Experiment
27(5)
1.9 Invariance of the Electric Charge
32(1)
1.10 The Solid Angle
33(3)
1.11 The Flux of E and the Gauss Theorem
36(3)
1.12 Graphic Representation of the Electric Field
39(2)
1.13 Applications of the Gauss Law
41(7)
1.14 Discontinuities of the Electric Field
48(2)
1.15 Poisson and Laplace Equations
50(1)
1.16 The Electric Dipole
51(5)
1.17 Dipole Approximation
56(5)
Summary
59(1)
Problems
59(2)
2 Conductors in Equilibrium
61(36)
2.1 Conductors
63(1)
2.2 Conductors in Equilibrium
64(5)
2.3 Surface Charges on a Conductor
69(3)
2.4 Hollow Conductors
72(4)
2.5 Equilibrium in an Electrostatic Field
76(1)
2.6 Electrostatic Capacitance
77(6)
2.7 Calculating Capacitances
83(2)
2.8 Combining Capacitors
85(2)
2.9 Electrostatic Induction Coefficients
87(1)
2.10 Electrostatic Shield
88(3)
2.11 The Method of Images
91(6)
Summary
93(1)
Problems
94(3)
3 Electrostatic Energy
97(16)
3.1 Energy of a System of Point Charges
98(1)
3.2 Energy of a Continuous Charge Distribution
99(2)
3.3 Energy of a System of Conductors
101(1)
3.4 Energy Stored in a Capacitor
102(1)
3.5 Energy in the Electrostatic Field
103(4)
3.6 The Energy of a Point Charge
107(6)
Summary
110(1)
Problems
110(3)
4 Dielectrics
113(34)
4.1 Dielectric Constant
114(2)
4.2 Polarization of a Dielectric
116(1)
4.3 Uniform Polarization
117(2)
4.4 Non-uniform Polarization
119(3)
4.5 Electrostatic Equations in a Dielectric
122(4)
4.6 Linear and Isotropic Dielectrics
126(2)
4.7 Electronic and Orientation Polarization
128(5)
4.8 Electric Field in Cavities in Dielectrics
133(5)
4.9 Electrostatic Energy in a Dielectric
138(9)
Summary
144(1)
Problems
145(2)
5 Electric Currents
147(30)
5.1 Current Intensity and Current Density
148(6)
5.2 Electric Charge Conservation
154(2)
5.3 Ohm's Law
156(4)
5.4 The British Association Ohm
160(2)
5.5 Surface Currents
162(2)
5.6 Energy Balance
164(1)
5.7 Generators
165(2)
5.8 Slow Capacitor Discharge
167(2)
5.9 Circuits in a Steady Regime
169(2)
5.10 Superconductivity
171(6)
Summary
174(1)
Problems
174(3)
6 Magnetostatics
177(64)
6.1 Preliminary Observations
179(2)
6.2 Magnetic Field
181(3)
6.3 Hall Effect
184(1)
6.4 Motion of Charges in a Magnetic Field
185(10)
6.5 Galvanometer
195(1)
6.6 The Magnetic Field of Steady Currents
196(7)
6.7 Applications of Ampere's Law
203(6)
6.8 The Vector Potential
209(3)
6.9 The Vector Potential in Simple Cases
212(4)
6.10 The Ampere-Laplace Law
216(1)
6.11 Examples of Magnetic Field Calculations
217(2)
6.12 Force Between Two Straight Steady Currents and the Ampere
219(1)
6.13 The Magnetic Dipole
220(5)
6.14 Charge Densities in a Current-Carrying Wire
225(4)
6.15 Properties of the Laws Under Rotations and Inversions of the Axes
229(2)
6.16 Relativity of Electric and Magnetic Forces
231(10)
Summary
237(1)
Problems
238(3)
7 Electromagnetic Induction
241(42)
7.1 The Flux Rule
242(3)
7.2 Induced Electric Field. Faraday's Law
245(4)
7.3 Exceptions to the Flux Rule
249(1)
7.4 Betatron
250(3)
7.5 Felici's Law
253(2)
7.6 Energy Balance
255(2)
7.7 Eddy Currents
257(3)
7.8 Mutual Induction
260(2)
7.9 Self-induction
262(4)
7.10 Inductive Phenomena in Electric Circuits
266(3)
7.11 Alternating Current Circuits
269(4)
7.12 Complex Impedance
273(6)
7.13 Energy Balance in a Circuit
279(4)
Summary
280(1)
Problems
280(3)
8 Magnetic Energy
283(14)
8.1 Energy of a Steady Current
284(1)
8.2 Energy of a System of Steady Currents
285(1)
8.3 Energy of a Dipole
286(4)
8.4 Energy of the Magnetic Field
290(7)
Summary
294(1)
Problems
294(3)
9 Magnetic Properties of Matter
297(42)
9.1 Elementary Observations
298(2)
9.2 Uniform Magnetization
300(3)
9.3 Non-uniform Magnetization
303(3)
9.4 Magnetic Field Equations in Matter
306(3)
9.5 B and H Fields in Matter
309(5)
9.6 Dia- and Para-magnetism. Microscopic Interpretation
314(5)
9.7 Ferromagnetism
319(4)
9.8 Uses of Ferromagnetism
323(4)
9.9 Microscopic Interpretation of Ferromagnetism
327(5)
9.10 Energy of Steady Currents in the Presence of Magnetic Materials
332(7)
Summary
335(1)
Problems
336(3)
10 Maxwell Equations
339(58)
10.1 Displacement Current
341(4)
10.2 Electromagnetic Waves
345(5)
10.3 The Maxwell Ratio of Units Experiment
350(7)
10.4 Energy Density in the Electromagnetic Field
357(3)
10.5 Energy Flux
360(3)
10.6 Momentum Density in the Electromagnetic Field
363(8)
10.7 Maxwell Equations in Matter
371(6)
10.8 Discontinuities of E and B
377(1)
10.9 The Electromagnetic Potentials
378(4)
10.10 Covariance of Electromagnetism
382(4)
10.11 Physical Meaning of the Electromagnetic Potentials
386(11)
Summary
394(1)
Problems
395(2)
Index 397
Alessandro Bettini is Emeritus Professor of Physics at the University of Padua, Italy, where he has taught experimental, general, and particle physics for 40 years. He is current Vice-president of the Italian Physical Society and his past posts also include Director of the INFN National Gran Sasso Laboratory, Vice-president of the OECD Global Science Forum, and Director of the Canfranc Underground Laboratory in Spain. Most recently, Professor Bettinis scientific interests have focused on neutrino physics beyond the standard model and astroparticle phenomena. He is a member of the GERDA experiment, searching for neutrino-less double beta decay. Professor Bettini is the author of approximately 200 articles in international scientific journals as well as several books, including Introduction to Elementary Particle Physics (Cambridge University Press, 2008, 2nd edn).