Matter and Interactions 3rd edition

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Ruth Chabay and Bruce Sherwood
Publisher: John Wiley & Sons

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  • Chapter 1: Interactions and Motion
    • 1.1: Kinds of Matter
    • 1.2: Detecting Interactions (5)
    • 1.3: Newton's First Law of Motion (6)
    • 1.4: Other Indicators of Interactions (1)
    • 1.5: Describing the 3D World: Vectors (40)
    • 1.6: SI Units (1)
    • 1.7: Velocity (11)
    • 1.8: Momentum (12)
    • 1.9: Change of Momentum (6)
    • 1.10: The Principle of Relativity* (1)
    • 1.11: Updating Position at High Speed*
    • Computational Problems
    • Computational Problems

  • Chapter 2: The Momentum Principle
    • 2.1: System and Surroundings
    • 2.2: The Momentum Principle (23)
    • 2.3: Applying the Momentum Principle (9)
    • 2.4: Momentum Change with Changing Force (1)
    • 2.5: Iterative Prediction of Motion (16)
    • 2.6: Special Case: Constant Force (14)
    • 2.7: Estimating Interaction Times (6)
    • 2.8: Physical Models
    • 2.9: Derivations: Special-Case Average Velocity*
    • 2.10: Inertial Frames*
    • 2.11: Measurements and Units*
    • Computational Problems
    • Computational Problems

  • Chapter 3: The Fundamental Interactions
    • 3.1: The Fundamental Interactions (1)
    • 3.2: The Gravitational Force (16)
    • 3.3: Approximate Gravitational Force Near the Earth's Surface (6)
    • 3.4: Reciprocity (1)
    • 3.5: Predicting Motion of Gravitationally Interacting Objects (5)
    • 3.6: The Electric Force (5)
    • 3.7: The Strong Interaction (1)
    • 3.8: Newton and Einstein
    • 3.9: Predicting the Future of Complex Systems (1)
    • 3.10: Determinism
    • 3.11: Conservation of Momentum (4)
    • 3.12: The Multiparticle Momentum Principle (2)
    • 3.13: Collisions: Negligible External Forces (14)
    • 3.14: Points and Spheres
    • 3.15: Measuring the Gravitational Constant G
    • Computational Problems
    • Computational Problems (2)

  • Chapter 4: Contact Interactions
    • 4.1: Tarzan and the Vine
    • 4.2: A Model of a Solid: Balls Connected by Springs
    • 4.3: Tension Forces
    • 4.4: Length of an Interatomic Bond (5)
    • 4.5: The Stiffness of an Interatomic Bond (3)
    • 4.6: Stress, Strain, and Young's Modulus (16)
    • 4.7: Compression (Normal) Forces (3)
    • 4.8: Friction (6)
    • 4.9: Speed of Sound in a Solid and Interatomic Bond Stiffness
    • 4.10: Derivative Form of the Momentum Principle (3)
    • 4.11: Analytical Solution: Spring-Mass System (12)
    • 4.12: Analytical Expression for Speed of Sound (5)
    • 4.13: Contact Forces Due to Gases (4)
    • 4.14: A Vertical Spring-Mass System*
    • 4.15: General Solution for the Mass-Spring System*
    • Computational Problems
    • Computational Problems

  • Chapter 5: Rate of Change of Momentum
    • 5.1: Identifying Forces on a System (2)
    • 5.2: Momentum Not Changing (Statics) (9)
    • 5.3: Finding the Rate of Change of Momentum (2)
    • 5.4: Curving Motion (5)
    • 5.5: Rate of Change of Direction (20)
    • 5.6: Why does the Vine Break? (6)
    • 5.7: Problem Solving (1)
    • Computational Problems
    • Computational Problems

  • Chapter 6: The Energy Principle
    • 6.1: The Energy Principle
    • 6.2: The Simplest System: A Single Particle (12)
    • 6.3: Work: Mechanical Energy Transfer (8)
    • 6.4: Update Form of the Energy Principle (10)
    • 6.5: Change of Rest Energy (2)
    • 6.6: Proof of the Energy Principle for a Particle
    • 6.7: Work Done by a Nonconstant Force (10)
    • 6.8: Potential Energy in Multiparticle Systems (3)
    • 6.9: Gravitational Potential Energy (7)
    • 6.10: General Properties of Potential Energy
    • 6.11: Plotting Energy vs. Separation (3)
    • 6.12: Applying Gravitational Potential Energy (9)
    • 6.13: Gravitational Potential Energy Near the Earth's Surface (1)
    • 6.14: Electric Potential Energy (4)
    • 6.15: The Mass of a Multiparticle System (9)
    • 6.16: Reflection: Why Energy?
    • 6.17: Identifying Initial and Final States
    • 6.18: A Puzzle*
    • 6.19: Gradient of Potential Energy*
    • 6.20: Integrals and Antiderivatives*
    • 6.21: Approximation for Kinetic Energy*
    • 6.22: Finding the Formula for Particle Energy*
    • Computational Problems
    • Computational Problems

  • Chapter 7: Internal Energy
    • 7.1: Potential Energy of Macroscopic Springs (8)
    • 7.2: Potential Energy of a Pair of Neutral Atoms (1)
    • 7.3: Path Independence of Potential Energy (2)
    • 7.4: Internal Energy and Thermal Energy (4)
    • 7.5: Energy Transfer due to a Temperature Difference (4)
    • 7.6: Reflection: Forms of Energy
    • 7.7: Power: Energy per Unit Time (6)
    • 7.8: Open and Closed Systems (1)
    • 7.9: The Choice of System Affects Energy Accounting (4)
    • 7.10: Energy Dissipation (10)
    • 7.11: Potential Energy and "Conservative" Forces (1)
    • 7.12: Resonance*
    • Computational Problems
    • Computational Problems

  • Chapter 8: Energy Quantization
    • 8.1: Photons
    • 8.2: Electronic Energy Levels (6)
    • 8.3: The Effect of Temperature (14)
    • 8.4: Vibrational Energy Levels (5)
    • 8.5: Rotational Energy Levels
    • 8.6: Other Energy Levels
    • 8.7: Comparison of Energy Level Spacings (1)
    • 8.8: Case Study: How a Laser Works*
    • 8.9: Wavelength of Light*
    • Computational Problems
    • Computational Problems

  • Chapter 9: Multiparticle Systems
    • 9.1: The Motion of the Center of Mass (4)
    • 9.2: Separation of Multiparticle System Energy (1)
    • 9.3: Rotational Kinetic Energy (7)
    • 9.4: The "Point Particle System" (6)
    • 9.5: Analyzing Point Particle and Real Systems (14)
    • 9.6: Modeling Friction in Detail*
    • 9.7: A Physical Model for Dry Friction* (1)
    • 9.8: Derivation: Kinetic Energy of a Multiparticle System*
    • 9.9: Derivation: The Point Particle Energy Equation
    • Computational Problems
    • Computational Problems

  • Chapter 10: Collisions
    • 10.1: Internal Interactions in Collisions (3)
    • 10.2: Elastic and Inelastic Collisions (4)
    • 10.3: A Head-On Collision of Equal Masses (1)
    • 10.4: Head-On Collisions Between Unequal Masses (3)
    • 10.5: Frame of Reference (8)
    • 10.6: Scattering: Collisions in 2-D and 3-D (1)
    • 10.7: Discovering the Nucleus Inside Atoms (2)
    • 10.8: Distribution of Scattering Angles*
    • 10.9: Relativistic Momentum and Energy (3)
    • 10.10: Inelastic Collisions and Quantized Energy
    • 10.11: Collisions in Other Reference Frames (2)
    • Computational Problems
    • Computational Problems

  • Chapter 11: Angular Momentum
    • 11.1: Translational Angular Momentum (11)
    • 11.2: Rotational Angular Momentum (13)
    • 11.3: Translational Plus Rotational Angular Momentum
    • 11.4: The Angular Momentum Principle (6)
    • 11.5: Multiparticle Systems
    • 11.6: Three Fundamental Principles of Mechanics (5)
    • 11.7: Systems with Zero Torque (16)
    • 11.8: Systems with Nonzero Torques (8)
    • 11.9: Predicting Positions when there is Rotation (1)
    • 11.10: Angular Momentum Quantization (4)
    • 11.11: Gyroscopes* (2)
    • 11.12: More Complex Rotational Situations*
    • 11.13: Rate of Change of a Rotating Vector*
    • Computational Problems
    • Computational Problems

  • Chapter 12: Entropy: Limits on the Possible
    • 12.1: Statistical Issues
    • 12.2: A Statistical Model of Solids (7)
    • 12.3: Thermal Equilibrium of Blocks in Contact (1)
    • 12.4: The Second Law of Thermodynamics (1)
    • 12.5: What is Temperature? (5)
    • 12.6: Specific Heat Capacity of a Solid (6)
    • 12.7: The Boltzmann Distribution (7)
    • 12.8: The Boltzmann Distribution in a Gas (13)
    • Computational Problems
    • Computational Problems

  • Chapter 13: Gases and Engines
    • 13.1: Gases, Solids and Liquids
    • 13.2: Gas Leaks Through a Hole (4)
    • 13.3: Mean Free Path (1)
    • 13.4: Pressure and Temperature (1)
    • 13.5: Energy Transfers (2)
    • 13.6: Fundamental Limitations on Efficiency (1)
    • 13.7: A Maximally Efficient Process (2)
    • 13.8: Why Don't We Attain the Theoretical Efficiency?*
    • 13.9: Application: A Random Walk* (1)
    • 13.10: Derivation: Maximum-Power Efficiency*
    • Computational Problems
    • Computational Problems

  • Chapter 14: Electric Field
    • 14.1: New Concepts
    • 14.2: Electric Charge and Force
    • 14.3: The Concept of "Electric Field (8)
    • 14.4: The Electric Field of a Point Charge (16)
    • 14.5: Superposition of Electric Fields (4)
    • 14.6: The Electric Field of a Dipole (14)
    • 14.7: Choice of System (2)
    • 14.8: Is Electric Field Real?
    • Computational Problems
    • Computational Problems

  • Chapter 15: Electric Fields and Matter
    • 15.1: Charged Particles in Matter (1)
    • 15.2: How Insulators Become Charged
    • 15.3: Polarization (3)
    • 15.4: Polarization of Insulators (6)
    • 15.5: Polarization of Conductors
    • 15.6: A Model of a Metal (8)
    • 15.7: Charging and Discharging (4)
    • 15.8: When the Field Concept is Less Useful
    • 15: Desktop Experiments (6)
    • Computational Problems
    • Computational Problems

  • Chapter 16: Electric Fields of Distributed Charges
    • 16.1: Overview
    • 16.2: A Uniformly Charged Thin Rod (6)
    • 16.3: Procedure for Calculating Electric Field (1)
    • 16.4: A Uniformly Charged Thin Ring (5)
    • 16.5: A Uniformly Charged Disk (5)
    • 16.6: Two Uniformly Charged Disks: A Capacitor (4)
    • 16.7: A Spherical Shell of Charge (14)
    • 16.8: A Solid Sphere Charged Throughout Its Volume
    • 16.9: Infinitesimals and Integrals in Science
    • 16.10: Uniform Thin Rod at an Arbitrary Location*
    • 16.11: Integrating the Spherical Shell*
    • Computational Problems
    • Computational Problems (4)

  • Chapter 17: Electric Potential
    • 17.1: A Review of Potential Energy (4)
    • 17.2: Systems of Charged Objects (3)
    • 17.3: Potential Difference in a Uniform Field (14)
    • 17.4: Sign of Potential Difference (9)
    • 17.5: Potential Difference in a Nonuniform Field (14)
    • 17.6: Path Independence (5)
    • 17.7: The Potential at One Location (11)
    • 17.8: Potential Difference in an Insulator (2)
    • 17.9: Energy Density and Electric Field (2)
    • 17.10: Potential of Distributed Charges* (1)
    • 17.11: Integrating the Spherical Shell*
    • Computational Problems
    • Computational Problems

  • Chapter 18: Magnetic Field
    • 18.1: Electron Current (2)
    • 18.2: Detecting Magnetic Fields (3)
    • 18.3: Biot-Savart Law: Single Moving Charge (14)
    • 18.4: Relativistic Effects
    • 18.5: Electron Current & Conventional Current (5)
    • 18.6: The Biot-Savart for Currents (1)
    • 18.7: The Magnetic Field of Current Distributions (8)
    • 18.8: A Circular Loop of Wire (6)
    • 18.9: Magnetic Dipole Moment (1)
    • 18.10: The Magnetic Field of a Bar Magnet (2)
    • 18.11: The Atomic Structure of Magnets (1)
    • 18.12: Estimate of Orbital Angular Momentum of an Electron in an Atom*
    • 18.13: Magnetic Field of a Solenoid*
    • Computational Problems
    • Computational Problems

  • Chapter 19: Electric Field and Circuits
    • 19.1: Overview
    • 19.2: Current in Different Parts of a Circuit (3)
    • 19.3: Electric Field and Current (8)
    • 19.4: What Charges make the Electric Field in the Wires?
    • 19.5: Connecting a Circuit: The Initial Transient (5)
    • 19.6: Feedback
    • 19.7: Surface Charge and Resistors
    • 19.8: Energy in a Circuit
    • 19.9: Applications of the Theory (14)
    • 19.10: Detecting Surface Charge
    • Computational Problems
    • Computational Problems

  • Chapter 20: Circuit Elements
    • 20.1: Capacitors (10)
    • 20.2: Resistors (12)
    • 20.3: Work and Power in a Circuit (4)
    • 20.4: Batteries (2)
    • 20.5: Ammeters, Voltmeters, and Ohmmeters
    • 20.6: Quantitative Analysis of an RC Circuit (1)
    • 20.7: Reflection: The Macro-Micro Connection
    • 20.8: What are AC and DC?*
    • 20.9: Electrons in Metals*
    • 20.10: A Complicated Resistive Circuit*
    • Computational Problems
    • Computational Problems

  • Chapter 21: Magnetic Force
    • 21.1: Magnetic Force on a Moving Charge (9)
    • 21.2: Magnetic Force on a Current-Carrying Wire (7)
    • 21.3: Combining Electric and Magnetic Forces (9)
    • 21.4: The Hall Effect (7)
    • 21.5: Motional EMF (6)
    • 21.6: Magnetic Force in Moving Reference Frame (1)
    • 21.7: Magnetic Torque
    • 21.8: Potential Energy for a Magnetic Dipole (1)
    • 21.9: Motors and Generators (3)
    • 21.10: Case Study: Sparks in Air* (7)
    • 21.11: Relativistic Field Transformations*
    • Computational Problems
    • Computational Problems

  • Chapter 22: Patterns of Field in Space
    • 22.1: Patterns of Electric Field: Gauss's Law
    • 22.2: Definition of "Electric Flux (3)
    • 22.3: Gauss's Law (6)
    • 22.4: Reasoning from Gauss's Law
    • 22.5: Gauss's Law for Magnetism (1)
    • 22.6: Patterns of Magnetic Field: Ampere's Law (2)
    • 22.7: Maxwell's Equations
    • 22.8: The Differential Form of Gauss's Law* (2)
    • 22.9: The Differential Form of Ampere's Law*
    • 22.10: Semiconductor Devices*
    • Computational Problems
    • Computational Problems

  • Chapter 23: Faraday's Law
    • 23.1: Curly Electric Fields (5)
    • 23.2: Faraday's Law (13)
    • 23.3: Faraday's Law and Motional EMF
    • 23.4: Maxwell's Equations
    • 23.5: Superconductors
    • 23.6: Inductance (3)
    • 23.7: Some Peculiar Circuits*
    • 23.8: The Differential Form of Faraday's Law*
    • 23.9: Lenz's Rule*
    • Computational Problems
    • Computational Problems

  • Chapter 24: Electromagnetic Radiation
    • 24.1: Maxwell's Equations (1)
    • 24.2: Fields Traveling Through Space (5)
    • 24.3: Accelerated Charges Produce Radiation (7)
    • 24.4: Sinusoidal Electromagnetic Radiation (4)
    • 24.5: Energy and Momentum in Radiation (4)
    • 24.6: Effects of Radiation on Matter (2)
    • 24.7: Light Propagation Through a Medium (1)
    • 24.8: Refraction: Bending of a Light (5)
    • 24.9: Lenses
    • 24.10: Image Formation
    • 24.11: The Field of an Accelerated Charge*
    • 24.12: Differential Form of Maxwell's Equations
    • Computational Problems
    • Computational Problems

  • Chapter 25: Waves and Particles
    • 25.1: Wave Phenomena (2)
    • 25.2: Multi-Source Interference: Diffractions (2)
    • 25.3: The Wave Model vs. the Particle Model of Light (6)
    • 25.4: Further Applications of the Wave Model (2)
    • 25.5: Angular Resolution (2)
    • 25.6: Standing Waves
    • 25.7: Derivation: Two Slits are like Two Sources
    • Computational Problems
    • Computational Problems

  • Chapter L1: Volume I Lab Resources
    • L1: Volume I Whiteboard Problems
    • L1: Volume I Experiments
    • Computational Problems
    • Computational Problems

  • Chapter L2: Volume II Lab Resources
    • L2: Volume II Whiteboard Problems
    • L2: Volume II Experiments
    • Computational Problems
    • Computational Problems


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Group Quantity Questions
Chapter 1: Interactions and Motion
1.2 5 X.001 X.002 X.047 X.047.alt01 X.048
1.3 6 X.003 X.004 X.049 X.049.alt01 X.050 X.051
1.4 1 X.005
1.5 40 X.006 X.007 X.008 X.009 X.010 X.011 X.012 X.013 X.014 X.015 X.016 X.017 X.018 X.019 X.020 X.021 X.022 X.023 X.024 X.025 X.026 X.026.01 X.027 X.058 X.059 X.061 X.062 X.062.alt01 X.063 X.065 X.072 X.074 X.077 X.077.alt01 X.078 X.083 X.084 X.085 X.085.alt01 X.085.alt02
1.6 1 X.028
1.7 11 X.029 X.030 X.031 X.032 X.033 X.034 X.035 X.036 X.091 X.092 X.093
1.8 12 X.037 X.038 X.039 X.040 X.041 X.105 X.106 X.107 X.111 X.112 X.113 X.114
1.9 6 P.117 P.117.draft X.042 X.042.alt01 X.043 X.044 X.116
1.10 1 X.045
Chapter 2: The Momentum Principle
2.2 23 P.038 P.039 P.040 P.041 P.042 P.043 X.001 X.002 X.003 X.004 X.005 X.026 X.027 X.028 X.029 X.030 X.031 X.032 X.033 X.034 X.035 X.036 X.037
2.3 9 X.006 X.007 X.008 X.009 X.010 X.044 X.045 X.045.alt01 X.045.alt02
2.4 1 X.011
2.5 16 P.047.01 P.049.01 X.012 X.013 X.014 X.015 X.016 X.017 X.018 X.019 X.020 X.020.01 X.046 X.047 X.048 X.049
2.6 14 P.057 P.058 P.063 X.021 X.022 X.023 X.024 X.050 X.051 X.052 X.053 X.054 X.055 X.056
2.7 6 P.066 P.067 P.068 P.069 X.025 X.065
Chapter 3: The Fundamental Interactions
3.C 2 P.080 P.081
3.1 1 X.026
3.2 16 P.036 X.001 X.002 X.003 X.004 X.005 X.006 X.008 X.027 X.028 X.029 X.030 X.031 X.032 X.033 X.034
3.3 6 P.040 X.009 X.010 X.037.alt01 X.038 X.039
3.4 1 X.011
3.5 5 P.042 P.043 P.044 P.045 P.045.alt01
3.6 5 P.052 P.053 X.013 X.014 X.054
3.7 1 X.015
3.9 1 X.016
3.11 4 X.017 X.018 X.019 X.020
3.12 2 X.022 X.023
3.13 14 P.058 P.062 P.063 P.065 P.067 P.068 P.069 P.070 P.072 P.079 X.024 X.025 X.055 X.056
Chapter 4: Contact Interactions
4.4 5 X.022 X.023 X.024 X.026 X.027
4.5 3 X.003 X.004 X.005
4.6 16 P.049 P.050 P.051 P.053 P.054 P.055 X.007 X.017.alt01 X.033 X.034 X.035 X.036 X.039 X.041 X.042 X.043
4.7 3 P.044 P.045 P.045.alt01 P.046
4.8 6 X.008 X.009 X.056 X.057 X.058 X.059
4.10 3 X.010 X.011 X.012
4.11 12 P.079 P.081 P.082 P.083 X.013 X.014 X.072 X.072.alt01 X.073 X.076 X.076.01 X.077
4.12 5 P.078 P.084 P.085 X.015 X.016
4.13 4 X.017 X.086 X.086.alt01 X.087
Chapter 5: Rate of Change of Momentum
5.1 2 X.001 X.012
5.2 9 P.014 P.015 P.016 P.017 P.018 P.019 X.002 X.003 X.013
5.3 2 X.004 X.023
5.4 5 X.005 X.006.01 X.020 X.021 X.026
5.5 20 P.045 P.045.alt01 P.046 P.053 P.054 P.057 P.062 P.063 P.064 P.065 P.066 P.067 X.008 X.009 X.010 X.010.01 X.031 X.032 X.033 X.034
5.6 6 P.044 P.047 P.048 P.049 P.050 P.055
5.7 1 X.037
Chapter 6: The Energy Principle
6.2 12 X.001 X.003 X.004 X.036 X.037 X.040 X.041 X.042 X.043 X.044 X.045 X.046
6.3 8 X.006 X.007 X.007.01 X.008 X.009 X.010 X.047 X.048
6.4 10 P.054 P.055 P.057 P.059 P.060 P.089 X.050 X.051 X.052 X.053
6.5 2 P.071 X.070
6.7 10 P.065 P.066 P.067 P.068 P.069 X.014 X.015 X.062 X.063 X.064
6.8 3 X.016 X.017 X.073
6.9 7 P.095 X.018 X.019 X.020 X.077 X.079 X.079.alt01
6.11 3 X.023 X.024 X.078
6.12 9 P.081 P.081.alt01 P.084 P.086 P.087 P.087.alt01 P.088 P.090 P.091
6.13 1 X.094
6.14 4 P.098 X.031 X.096 X.097
6.15 9 P.099 P.100 P.100.alt01 P.101 P.101.alt01 P.102 P.102.alt01 P.102.alt02 P.103
Chapter 7: Internal Energy
7.1 8 P.029 P.033 P.035 P.036 X.001 X.002 X.022 X.025
7.2 1 P.032
7.3 2 X.024 X.027
7.4 4 P.045 P.051.alt01 X.006 X.007
7.5 4 P.046 X.008 X.009 X.010
7.7 6 P.047 P.049 P.050 X.011 X.012 X.041
7.8 1 X.040
7.9 4 X.013 X.042 X.043 X.044
7.10 10 P.061 P.062 P.062.alt01 X.014 X.016 X.019 X.056 X.056.alt01 X.057 X.058
7.11 1 X.019.01
Chapter 8: Energy Quantization
8.2 6 X.003 X.005 X.006 X.007 X.014 X.015
8.3 14 P.020 P.021 P.023 P.024 P.025 P.026 P.027 P.027.alt01 P.028 P.028.alt01 P.029 X.016 X.017 X.019
8.4 5 P.034 P.036 X.009 X.010 X.011
8.7 1 X.033
Chapter 9: Multiparticle Systems
9.1 4 P.020 X.001 X.004 X.015
9.2 1 X.019
9.3 7 P.022 X.005 X.006 X.007 X.008 X.009 X.010
9.4 6 P.029 X.012 X.012.alt01 X.012.alt02 X.023 X.027
9.5 14 P.033 P.034 P.035 P.037 P.038 P.040 P.041 P.042 P.043 P.043.alt01 P.044 P.044.alt01 P.045 X.032
9.7 1 P.046
Chapter 10: Collisions
10.1 3 X.007 X.009 X.010
10.2 4 P.013 P.013.alt01 X.011 X.012
10.3 1 X.001
10.4 3 X.002 X.003 X.019
10.5 8 P.021 P.022 P.023 X.015 X.016 X.017 X.018 X.020
10.6 1 X.026
10.7 2 P.031 P.032
10.9 3 P.034 P.035 P.036
10.11 2 X.005 X.006
Chapter 11: Angular Momentum
11.1 11 X.002 X.002.01 X.002.02 X.002.alt01 X.026 X.027 X.028 X.029 X.030 X.031 X.031.alt01
11.2 13 P.039 P.040 X.005 X.005.01 X.006 X.006.alt01 X.007 X.032 X.033 X.034 X.035 X.036 X.037
11.4 6 P.050 X.011 X.012 X.044 X.047 X.048
11.6 5 X.016 X.017 X.018 X.018.alt01 X.019
11.7 16 P.055 P.056 P.057 P.059 P.059.alt01 P.060 P.061 P.063 P.065 P.066 P.068 P.069 P.070 X.052 X.053 X.054
11.8 8 P.074 P.075 P.079 P.080 P.081 X.071 X.072 X.073
11.9 1 X.022
11.10 4 P.087 P.088 X.083 X.084
11.11 2 P.093 P.094
Chapter 12: Entropy: Limits on the Possible
12.2 7 X.001 X.004 X.004.01 X.027 X.028 X.029 X.030
12.3 1 X.038
12.4 1 X.036
12.5 5 P.039 P.042 X.008 X.009 X.037
12.6 6 P.040 P.041 P.043 P.045 P.047 X.010
12.7 7 X.011 X.014 X.049 X.050 X.053 X.057 X.058
12.8 13 P.062 P.063 P.064 P.065 P.066 P.067 X.016 X.018 X.019 X.052 X.056 X.059 X.060
Chapter 13: Gases and Engines
13.2 4 P.019 P.020 P.021 X.002 X.016
13.3 1 X.017
13.4 1 P.023
13.5 2 P.026 X.005
13.6 1 X.008
13.7 2 X.011 X.012
13.9 1 X.014
Chapter 14: Electric Field
14.3 8 P.022 P.023 P.025 X.003.01 X.003.02 X.016 X.017 X.018
14.4 16 P.041 P.042 P.044 P.046 X.005 X.006 X.006.alt01 X.007 X.008 X.028 X.029 X.029.alt01 X.029.alt02 X.030 X.032 X.032.alt01 X.7a X.7b X.7c
14.5 4 P.049.01 P.052 P.052.alt01 P.053
14.6 14 P.070 P.070.alt01 P.071 P.071.alt01 P.073 X.010 X.010.alt01 X.010.alt02 X.010.alt03 X.059 X.061 X.061.alt01 X.062 X.063
14.7 2 X.013 X.014
Chapter 15: Electric Fields and Matter
15.EXP 6 013 014 015 017 018 019
15.1 1 X.028
15.3 3 X.005 X.006 X.007
15.4 6 EXP.019.01 P.042.alt01 P.048 X.034 X.035 X.047
15.6 8 P.064 P.064.alt01 P.064.alt02 P.067 P.069 X.052 X.052.alt01 X.054
15.7 4 P.079 X.077 X.077.alt01 X.078
Chapter 16: Electric Fields of Distributed Charges
16.C 4 P.068 P.069 P.069.alt02 P.069.alt03
16.2 6 X.001 X.017 X.018 X.018.alt01 X.019 X.020
16.3 1 X.021
16.4 5 P.043 P.043.alt01 X.032 X.033 X.034
16.5 5 P.058 X.005 X.005.alt01 X.005.alt02 X.035
16.6 4 P.039 P.042.alt01 X.006 X.040
16.7 14 P.061 P.062 P.062.alt01 P.064 P.065 X.009 X.053 X.053.alt01 X.053.alt02 X.053.alt03 X.053.alt04 X.055 X.056 X.056.alt01
Chapter 17: Electric Potential
17.1 4 X.020 X.021 X.022 X.024
17.2 3 X.023 X.026 X.027
17.3 14 P.045 P.046 P.047 X.030 X.031 X.032 X.033 X.034 X.035 X.036 X.037 X.043 X.044 X.049
17.4 9 X.008 X.009 X.048 X.050 X.051 X.052 X.053 X.054 X.055
17.5 14 P.060 P.061 P.063 P.065 P.067 P.069 P.072 P.072.alt01 P.073 P.073.alt01 X.056 X.057 X.058 X.059
17.6 5 P.076 P.076.alt01 P.076.alt02 P.082 X.075
17.7 11 P.094 P.094.alt01 P.098 X.084 X.085 X.086 X.087 X.088 X.089 X.093 X.093.alt02
17.8 2 P.103 X.016
17.9 2 X.017 X.018
17.10 1 X.019
Chapter 18: Magnetic Field
18.1 2 X.001 X.002
18.2 3 X.003 X.039 X.040
18.3 14 P.038 P.041 X.004 X.004.alt01 X.026 X.027 X.028 X.029 X.033 X.034 X.035 X.035.alt01 X.036 X.037
18.5 5 X.008 X.009 X.042 X.043 X.044
18.6 1 X.051
18.7 8 P.055 P.057 P.061 P.062 P.067 P.068 X.047 X.049
18.8 6 P.059 P.064 P.065 X.050 X.052 X.053
18.9 1 X.011
18.10 2 P.073 P.076
18.11 1 X.072
Chapter 19: Electric Field and Circuits
19.2 3 X.001 X.029 X.030
19.3 8 P.041 P.042 P.044 X.003 X.004 X.005 X.039 X.040
19.5 5 X.048 X.049 X.050 X.051 X.051.alt01
19.9 14 P.063 P.064 P.065 P.066 P.067 P.069 P.069.alt01 P.069.alt02 P.070 X.056 X.057 X.062 X.072 X.072.alt01
Chapter 20: Circuit Elements
20.1 10 P.060 P.062 X.031 X.032.alt01 X.032.alt02 X.032.alt03 X.032.alt04 X.047 X.048 X.049
20.2 12 P.073 P.075 X.008 X.009 X.010 X.011 X.012 X.013 X.064 X.065 X.068 X.071
20.3 4 P.082 P.082.alt01 P.084 X.014
20.4 2 P.087 P.088
20.6 1 P.094
Chapter 21: Magnetic Force
21.1 9 P.039 P.041 P.044 X.001 X.003 X.031 X.032 X.033 X.035
21.2 7 P.051 P.051.alt01 X.004 X.047 X.047.alt01 X.048 X.048.alt01
21.3 9 P.057 P.058 P.059 X.005 X.006 X.007 X.054 X.055 X.056
21.4 7 P.066 P.067 P.068 X.008 X.008.alt01 X.009 X.063
21.5 6 P.082 P.084 X.010 X.075 X.076 X.078
21.6 1 X.012
21.8 1 X.015
21.9 3 X.018 X.019 X.091
21.10 7 X.020 X.021 X.022 X.023 X.098 X.099 X.100
Chapter 22: Patterns of Field in Space
22.2 3 X.001 X.001.alt01 X.010
22.3 6 P.014 P.015 P.015.alt01 P.019 X.011 X.011.alt01
22.5 1 X.027
22.6 2 X.004 X.028
22.8 2 X.005 X.006
Chapter 23: Faraday's Law
23.1 5 X.001 X.002 X.003 X.004 X.004.alt01
23.2 13 P.027 P.028.alt01 P.029 P.030 P.036 P.036.alt01 P.038 X.005 X.006 X.007 X.008 X.009 X.021
23.6 3 P.052 X.015 X.017
Chapter 24: Electromagnetic Radiation
24.1 1 X.020
24.2 5 X.001 X.023 X.024 X.025 X.026
24.3 7 X.006 X.030 X.033 X.034 X.035 X.035.alt01 X.036
24.4 4 X.038 X.038.01 X.039 X.040
24.5 4 P.041 P.043 X.009 X.010
24.6 2 X.011 X.050
24.7 1 X.052
24.8 5 P.057 X.053 X.054 X.055 X.056
Chapter 25: Waves and Particles
25.1 2 P.021 X.004
25.2 2 X.007 X.008
25.3 6 X.009 X.010 X.011 X.012 X.013 X.027
25.4 2 X.014 X.036
25.5 2 X.015 X.016
Total 1041 (6)