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Matter and Interactions, Volume 2: Electric and Magnetic Interactions 4th ed. [Loose-leaf]

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, (North Carolina State University)
  • Formatas: Loose-leaf, 1040 pages, aukštis x plotis x storis: 274x211x38 mm, weight: 2018 g
  • Išleidimo metai: 24-Jul-2018
  • Leidėjas: Wiley
  • ISBN-10: 1119462037
  • ISBN-13: 9781119462033
Kitos knygos pagal šią temą:
Matter and Interactions, Volume 2: Electric and Magnetic Interactions 4th ed.Didesnis paveikslėlis
  • Formatas: Loose-leaf, 1040 pages, aukštis x plotis x storis: 274x211x38 mm, weight: 2018 g
  • Išleidimo metai: 24-Jul-2018
  • Leidėjas: Wiley
  • ISBN-10: 1119462037
  • ISBN-13: 9781119462033
Kitos knygos pagal šią temą:
Pastovi nuoroda: https://www.kriso.lt/db/9781119462033.html
Matter and Interactions, Volume II offers a modern curriculum for introductory physics (calculus-based). It presents physics the way practicing physicists view their discipline while integrating 20th Century physics and computational physics. The text emphasizes the small number of fundamental principles that underlie the behavior of matter, and models that can explain and predict a wide variety of physical phenomena. Matter and Interactions will be available as a single volume hardcover text and also two paperback volumes.

Volume Two includes chapters 13-23.
Chapter 13 Electric Field 513(33)
13.1 New Concepts
513(1)
13.2 Electric Charge and Force
513(2)
13.3 The Concept of "Electric Field"
515(4)
13.4 The Electric Field of a Point Charge
519(3)
13.5 Superposition of Electric Fields
522(2)
13.6 The Electric Field of a Dipole
524(8)
13.7 Choice of System
532(1)
13.8 Is Electric Field Real?
533(2)
13.9 Computational Modeling of Electric Fields
535(3)
Summary
538(1)
Questions
539(1)
Problems
540(4)
Computational Problems
544(1)
Answers to Checkpoints
545(1)
Chapter 14 Electric Fields and Matter 546(42)
14.1 Charged Particles in Matter
546(2)
14.2 How Objects Become Charged
548(3)
14.3 Polarization of Atoms
551(6)
14.4 Polarization of Insulators
557(1)
14.5 Polarization of Conductors
558(3)
14.6 Charge Motion in Metals
561(7)
14.7 Charge Transfer
568(2)
14.8 Practical Issues in Measuring Electric Field
570(1)
Summary
571(1)
Experiments
572(6)
Questions
578(2)
Problems
580(6)
Answers to Checkpoints
586(2)
Chapter 15 Electric Field of Distributed Charges 588(38)
15.1 A Uniformly Charged Thin Rod
588(7)
15.2 Procedure for Calculating Electric Field
595(2)
15.3 A Uniformly Charged Thin Ring
597(2)
15.4 A Uniformly Charged Disk
599(4)
15.5 Two Uniformly Charged Disks: A Capacitor
603(3)
15.6 A Spherical Shell of Charge
606(2)
15.7 A Solid Sphere Charged Throughout its Volume
608(1)
15.8 Infinitesimals and Integrals in Science
609(1)
15.9 3D Numerical Integration with a Computer
610(3)
15.10 Integrating the Spherical Shell
613(1)
Summary
614(2)
Questions
616(1)
Problems
617(7)
Computational Problems
624(1)
Answers to Checkpoints
625(1)
Chapter 16 Electric Potential 626(47)
16.1 A Review of Potential Energy
626(3)
16.2 Systems of Charged Objects
629(3)
16.3 Potential Difference in a Uniform Field
632(3)
16.4 Sign of Potential Difference
635(2)
16.5 Potential Difference in a Nonuniform Field
637(7)
16.6 Path Independence
644(4)
16.7 The Potential at One Location
648(4)
16.8 Computing Potential Differences
652(1)
16.9 Potential Difference in an Insulator
653(3)
16.10 Energy Density and Electric Field
656(2)
16.11 Potential of Distributed Charges
658(1)
16.12 Integrating the Spherical Shell
658(2)
16.13 Numerical Integration Along a Path
660(1)
Summary
661(1)
Questions
661(2)
Problems
663(9)
Computational Problems
672(1)
Answers to Checkpoints
672(1)
Chapter 17 Magnetic Field 673(43)
17.1 Electron Current
673(1)
17.2 Detecting Magnetic Fields
674(2)
17.3 Biot-Savart Law: Single Moving Charge
676(2)
17.4 Relativistic Effects
678(1)
17.5 Electron Current and Conventional Current
679(3)
17.6 The Biot-Savart Law for Currents
682(1)
17.7 The Magnetic Field of Current Distributions
683(3)
17.8 A Circular Loop of Wire
686(3)
17.9 Computation and 3D Visualization
689(1)
17.10 Magnetic Dipole Moment
690(1)
17.11 The Magnetic Field of a Bar Magnet
691(2)
17.12 The Atomic Structure of Magnets
693(6)
17.13 Estimate of Orbital Angular Momentum of an Electron in an Atom
699(1)
17.14 Magnetic Field of a Solenoid
700(2)
Summary
702(1)
Experiments
703(4)
Questions
707(1)
Problems
708(5)
Computational Problems
713(2)
Answers to Checkpoints
715(1)
Chapter 18 Electric Field and Circuits 716(49)
18.1 A Circuit Is Not in Equilibrium
716(1)
18.2 Current in Different Parts of a Circuit
717(3)
18.3 Electric Field and Current
720(2)
18.4 What Charges Make the Electric Field Inside the Wires?
722(4)
18.5 Surface Charge Distributions
726(6)
18.6 Connecting a Circuit: The Initial Transient
732(2)
18.7 Feedback
734(1)
18.8 Surface Charge and Resistors
735(3)
18.9 Energy in a Circuit
738(4)
18.10 Applications of the Theory
742(5)
18.11 Detecting Surface Charge
747(2)
18.12 Computational Model of a Circuit
749(2)
Summary
751(1)
Experiments
752(3)
Questions
755(2)
Problems
757(6)
Answers to Checkpoints
763(2)
Chapter 19 Circuit Elements 765(40)
19.1 Capacitors
765(6)
19.2 Resistors
771(5)
19.3 Conventional Symbols and Terms
776(1)
19.4 Work and Power in a Circuit
777(2)
19.5 Batteries
779(2)
19.6 Ammeters, Voltmeters, and Ohmmeters
781(2)
19.7 Quantitative Analysis of an RC Circuit
783(3)
19.8 Reflection: The Macro-Micro Connection
786(1)
19.9 What Are AC and DC?
787(2)
19.10 Electrons in Metals
789(1)
19.11 A Complicated Resistive Circuit
789(3)
Summary
792(1)
Experiments
792(2)
Questions
794(3)
Problems
797(6)
Answers to Checkpoints
803(2)
Chapter 20 Magnetic Force 805(62)
20.1 Magnetic Force on a Moving Charge
805(5)
20.2 Magnetic Force on a Current-Carrying Wire
810(2)
20.3 Combining Electric and Magnetic Forces
812(2)
20.4 The Hall Effect
814(5)
20.5 Motional Emf
819(5)
20.6 Magnetic Force in a Moving Reference Frame
824(4)
20.7 Magnetic Torque
828(1)
20.8 Potential Energy for a Magnetic Dipole
829(5)
20.9 Motors and Generators
834(2)
20.10 Case Study: Sparks in Air
836(10)
20.11 Relativistic Field Transformations
846(4)
Summary
850(1)
Experiments
851(1)
Questions
851(3)
Problems
854(10)
Computational Problems
864(2)
Answers to Checkpoints
866(1)
Chapter 21 Patterns of Field in Space 867(35)
21.1 Patterns of Electric Field: Gauss's Law
867(2)
21.2 Definition of "Electric Flux"
869(2)
21.3 Gauss's Law
871(6)
21.4 Reasoning from Gauss's Law
877(5)
21.5 Gauss's Law for Magnetism
882(1)
21.6 Patterns of Magnetic Field: Ampere's Law
883(6)
21.7 Maxwell's Equations
889(1)
21.8 Semiconductor Devices
889(1)
21.9 The Differential Form of Gauss's Law
889(6)
21.10 The Differential Form of Ampere's Law
895(1)
Summary
896(1)
Questions
897(1)
Problems
897(4)
Computational Problem
901(1)
Answers to Checkpoints
901(1)
Chapter 22 Faraday's Law 902(37)
22.1 Curly Electric Fields
902(3)
22.2 Faraday's Law
905(7)
22.3 Faraday's Law and Motional Era
912(3)
22.4 Maxwell's Equations
915(1)
22.5 Superconductors
916(2)
22.6 Inductance
918(4)
22.7 Inductor Circuits
922(4)
22.8 Some Peculiar Circuits
926(2)
22.9 The Differential Form of Faraday's Law
928(1)
22.10 Lenz's Rule
929(1)
Summary
930(1)
Questions
931(1)
Problems
932(6)
Answers to Checkpoints
938(1)
Chapter 23 Electromagnetic Radiation 939(53)
23.1 Maxwell's Equations
939(3)
23.2 Fields Traveling Through Space
942(5)
23.3 Accelerated Charges Produce Radiation
947(4)
23.4 Sinusoidal Electromagnetic Radiation
951(4)
23.5 Energy and Momentum in Radiation
955(4)
23.6 Effects of Radiation on Matter
959(5)
23.7 Light Propagation Through a Medium
964(2)
23.8 Refraction: Bending of Light
966(3)
23.9 Lenses
969(3)
23.10 Image Formation
972(11)
23.11 The Field of an Accelerated Charge
983(2)
23.12 Differential Form of Maxwell's Equations
985(1)
Summary
986(1)
Questions
986(2)
Problems
988(3)
Computational Problems
991(1)
Answers to Checkpoints 992
Answers to Odd-Numbered Problems A-1
Index I-1