Physics for Scientists and Engineers 2nd edition

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Randall D. Knight
Publisher: Pearson Education


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  • Chapter 1: Concepts of Motion
    • 1.1: Motion Diagrams
    • 1.2: The Particle Model
    • 1.3: Position and Time (1)
    • 1.4: Velocity (1)
    • 1.5: Acceleration
    • 1.6: Examples of Motion Diagrams
    • 1.7: From Words to Symbols
    • 1.8: A Problem-Solving Strategy
    • 1.9: Units and Significant Figures (10)
    • 1: Problems (5)

  • Chapter 2: Kinematics in One Dimension
    • 2.1: Uniform Motion (5)
    • 2.2: Instantaneous Velocity
    • 2.3: Finding Position from Velocity (1)
    • 2.4: Motion with Constant Acceleration (6)
    • 2.5: Free Fall (3)
    • 2.6: Motion on an Inclined Plane (1)
    • 2.7: Instantaneous Acceleration (3)
    • 2: Problems (23)

  • Chapter 3: Vectors and Coordinate Systems
    • 3.1: Vectors
    • 3.2: Properties of Vectors
    • 3.3: Coordinate Systems and Vector Components (6)
    • 3.4: Vector Algebra (4)
    • 3: Problems (19)

  • Chapter 4: Kinematics in Two Dimensions
    • 4.1: Acceleration (1)
    • 4.2: Two-Dimensional Kinematics (3)
    • 4.3: Projectile Motion (4)
    • 4.4: Relative Motion (2)
    • 4.5: Uniform Circular Motion (3)
    • 4.6: Velocity and Acceleration in Uniform Circular Motion (3)
    • 4.7: Nonuniform Circular Motion and Angular Acceleration (2)
    • 4: Problems (21)

  • Chapter 5: Force and Motion
    • 5.1: Force
    • 5.2: A Short Catalog of Forces
    • 5.3: Identifying Forces (3)
    • 5.4: What Do Forces Do? A Virtual Experiment (3)
    • 5.5: Newton's Second Law (4)
    • 5.6: Newton's First Law
    • 5.7: Free-Body Diagrams
    • 5: Problems (2)
    • 5: Challenge Problems

  • Chapter 6: Dynamics I: Motion Along a Line
    • 6.1: Equilibrium (4)
    • 6.2: Using Newton's Second Law (6)
    • 6.3: Mass, Weight, and Gravity (3)
    • 6.4: Friction (4)
    • 6.5: Drag (2)
    • 6.6: More Examples of Newton's Second Law
    • 6: Problems (20)
    • 6: Challenge Problem (3)

  • Chapter 7: Newton's Third Law
    • 7.1: Interacting Objects
    • 7.2: Analyzing Interacting Objects
    • 7.3: Newton's Third Law (4)
    • 7.4: Ropes and Pulleys (3)
    • 7.5: Examples of Interacting-Object Problems
    • 7: Problems (21)
    • 7: Challenge Problems (4)

  • Chapter 8: Dynamics II: Motion in a Plane
    • 8.1: Dynamics in Two Dimensions (3)
    • 8.2: Velocity and Acceleration in Uniform Circular Motion
    • 8.3: Dynamics of Uniform Circular Motion (6)
    • 8.4: Circular Orbits (1)
    • 8.5: Fictitious Forces
    • 8.6: Why Does the Water Stay in the Bucket? (4)
    • 8.7: Nonuniform Circular Motion (1)
    • 8: Problems (17)
    • 8: Challenge Problems (4)

  • Chapter 9: Impulse and Momentum
    • 9.1: Momentum and Impulse (3)
    • 9.2: Solving Impulse and Momentum Problems (5)
    • 9.3: Conservation of Momentum (2)
    • 9.4: Inelastic Collisions (3)
    • 9.5: Explosions (2)
    • 9.6: Momentum in Two Dimensions (2)
    • 9: Problems (17)
    • 9: Challenge Problems (4)

  • Chapter 10: Energy
    • 10.1: A “Natural Money” Called Energy
    • 10.2: Kinetic Energy and Gravitational Potential Energy (3)
    • 10.3: A Closer Look at Gravitational Potential Energy (4)
    • 10.4: Restoring Forces and Hooke's Law (4)
    • 10.5: Elastic Potential Energy (4)
    • 10.6: Elastic Collisions (3)
    • 10.7: Energy Diagrams (1)
    • 10: Problems (16)
    • 10: Challenge Problems (5)

  • Chapter 11: Work
    • 11.1: The Basic Energy Model
    • 11.2: Work and Kinetic Energy
    • 11.3: Calculating and Using Work (9)
    • 11.4: The Work Done by a Variable Force (3)
    • 11.5: Force, Work, and Potential Energy
    • 11.6: Finding Force from Potential Energy
    • 11.7: Thermal Energy (2)
    • 11.8: Conservation of Energy (1)
    • 11.9: Power (3)
    • 11: Problems (20)
    • 11: Challenge Problems (2)

  • Chapter 12: Rotation of a Rigid Body
    • 12.1: Rotational Motion (1)
    • 12.2: Rotation About the Center of Mass (1)
    • 12.3: Rotational Energy (2)
    • 12.4: Calculating Moment of Inertia (3)
    • 12.5: Torque (3)
    • 12.6: Rotational Dynamics
    • 12.7: Rotation About a Fixed Axis (3)
    • 12.8: Static Equilibrium (3)
    • 12.9: Rolling Motion (2)
    • 12.10: The Vector Description of Rotational Motion (1)
    • 12.11: Angular Momentum of a Rigid Body (2)
    • 12: Problems (13)
    • 12: Challenge Problems (1)

  • Chapter 13: Newton's Theory of Gravity
    • 13.1: A Little History
    • 13.2: Isaac Newton
    • 13.3: Newton's Law of Gravity (3)
    • 13.4: Little g and Big G (2)
    • 13.5: Gravitational Potential Energy (1)
    • 13.6: Satellite Orbits and Energies (4)
    • 13: Problems (17)
    • 13: Challenge Problems

  • Chapter 14: Oscillations
    • 14.1: Simple Harmonic Motion (1)
    • 14.2: Simple Harmonic Motion and Circular Motion (1)
    • 14.3: Energy in Simple Harmonic Motion
    • 14.4: The Dynamics of Simple Harmonic Motion (3)
    • 14.5: Vertical Oscillations (2)
    • 14.6: The Pendulum (1)
    • 14.7: Damped Oscillations
    • 14.8: Driven Oscillations and Resonance (3)
    • 14: Problems (14)
    • 14: Challenge Problems (1)

  • Chapter 15: Fluids and Elasticity
    • 15.1: Fluids (2)
    • 15.2: Pressure (2)
    • 15.3: Measuring and Using Pressure (1)
    • 15.4: Buoyancy (2)
    • 15.5: Fluid Dynamics (2)
    • 15.6: Elasticity (3)
    • 15: Problems (13)
    • 15: Challenge Problems (1)

  • Chapter 16: A Macroscopic Description of Matter
    • 16.1: Solids, Liquids, and Gases (2)
    • 16.2: Atoms and Moles (1)
    • 16.3: Temperature
    • 16.4: Phase Changes (2)
    • 16.5: Ideal Gases (3)
    • 16.6: Ideal-Gas Processes (2)
    • 16: Problems (10)
    • 16: Challenge Problems (1)

  • Chapter 17: Work, Heat, and the First Law of Thermodynamics
    • 17.1: It's All About Energy
    • 17.2: Work in Ideal-Gas Processes (2)
    • 17.3: Heat
    • 17.4: The First Law of Thermodynamics (1)
    • 17.5: Thermal Properties of Matter (5)
    • 17.6: Calorimetry (2)
    • 17.7: The Specific Heats of Gases (4)
    • 17.8: Heat-Transfer Mechanisms
    • 17: Problems (11)
    • 17: Challenge Problems

  • Chapter 18: The Micro-Macro Connection
    • 18.1: Molecular Speeds and Collisions (4)
    • 18.2: Pressure in a Gas (3)
    • 18.3: Temperature (5)
    • 18.4: Thermal Energy and Specific Heat (6)
    • 18.5: Thermal Interactions and Heat (1)
    • 18.6: Irreversible Processes and the Second Law of Thermodynamics
    • 18: Problems (9)
    • 18: Challenge Problems

  • Chapter 19: Heat Engines and Refrigerators
    • 19.1: Turning Heat into Work
    • 19.2: Heat Engines and Refrigerators (4)
    • 19.3: Ideal-Gas Heat Engines
    • 19.4: Ideal-Gas Refrigerators (1)
    • 19.5: The Limits of Efficiency
    • 19.6: The Carnot Cycle (6)
    • 19: Problems (12)
    • 19: Challenge Problems

  • Chapter 20: Traveling Waves
    • 20.1: The Wave Model (2)
    • 20.2: One-Dimensional Waves
    • 20.3: Sinusoidal Waves (4)
    • 20.4: Waves in Two and Three Dimensions (2)
    • 20.5: Sound and Light (5)
    • 20.6: Power, Intensity, and Decibels (4)
    • 20.7: The Doppler Effect (2)
    • 20: Problems (14)
    • 20: Challenge Problems (2)

  • Chapter 21: Superposition
    • 21.1: The Principle of Superposition
    • 21.2: Standing Waves
    • 21.3: Transverse Standing Waves (4)
    • 21.4: Standing Sound Waves and Musical Acoustics (4)
    • 21.5: Interference in One Dimension
    • 21.6: The Mathematics of Interference (5)
    • 21.7: Interference in Two and Three Dimensions (2)
    • 21.8: Beats (2)
    • 21: Problems (13)
    • 21: Challenge Problems (1)

  • Chapter 22: Wave Optics
    • 22.1: Light and Optics
    • 22.2: The Interference of Light (7)
    • 22.3: The Diffraction Grating (5)
    • 22.4: Single-Slit Diffraction (3)
    • 22.5: Circular-Aperture Diffraction (3)
    • 22.6: Interferometers (2)
    • 22: Problems (16)
    • 22: Challenge Problems (2)

  • Chapter 23: Ray Optics
    • 23.1: The Ray Model of Light (2)
    • 23.2: Reflection (4)
    • 23.3: Refraction (4)
    • 23.4: Image Formation by Refraction (2)
    • 23.5: Color and Dispersion (3)
    • 23.6: Thin Lenses: Ray Tracing
    • 23.7: Thin Lenses: Refraction Theory (2)
    • 23.8: Image Formation with Spherical Mirrors
    • 23: Problems (16)
    • 23: Challenge Problems (1)

  • Chapter 24: Optical Instruments
    • 24.1: Lenses in Combination
    • 24.2: The Camera
    • 24.3: Vision
    • 24.4: Optical Systems that Magnify
    • 24.5: The Resolution of Optical Instruments (1)
    • 24: Problems (5)
    • 24: Challenge Problems (1)

  • Chapter 25: Modern Optics and Matter Waves
    • 25.1: Spectroscopy: Unlocking the Structure of Atoms (2)
    • 25.2: X-Ray Diffraction (4)
    • 25.3: Photons (3)
    • 25.4: Matter Waves (2)
    • 25.5: Energy is Quantized (3)
    • 25: Problems (12)
    • 25: Challenge Problems

  • Chapter 26: Electric Charges and Forces
    • 26.1: Developing a Charge Model
    • 26.2: Charge (2)
    • 26.3: Insulators and Conductors
    • 26.4: Coulomb's Law (3)
    • 26.5: The Field Model (3)
    • 26: Problems (17)
    • 26: Challenge Problems (1)

  • Chapter 27: The Electric Field
    • 27.1: Electric Field Models
    • 27.2: The Electric Field of Multiple Point Charges (4)
    • 27.3: The Electric Field of a Continuous Charge Distribution (3)
    • 27.4: The Electric Fields of Rings, Disks, Planes, and Spheres (4)
    • 27.5: The Parallel-Plate Capacitor (1)
    • 27.6: Motion of a Charged Particle in an Electric Field (3)
    • 27.7: Motion of a Dipole in an Electric Field (2)
    • 27: Problems (14)
    • 27: Challenge Problems (3)

  • Chapter 28: Gauss's Law
    • 28.1: Symmetry
    • 28.2: The Concept of Flux (3)
    • 28.3: Calculating Electric Flux (4)
    • 28.4: Gauss's Law
    • 28.5: Using Gauss's Law (4)
    • 28.6: Conductors in Electrostatic Equilibrium (3)
    • 28: Problems (15)
    • 28: Challenge Problems

  • Chapter 29: The Electric Potential
    • 29.1: Electric Potential Energy (2)
    • 29.2: The Potential Energy of Point Charges (2)
    • 29.3: The Potential Energy of a Dipole (2)
    • 29.4: The Electric Potential (3)
    • 29.5: The Electric Potential Inside a Parallel-Plate Capacitor (1)
    • 29.6: The Electric Potential of a Point Charge (2)
    • 29.7: The Electric Potential of Many Charges (2)
    • 29: Problems (13)
    • 29: Challenge Problems (3)

  • Chapter 30: Potential and Field
    • 30.1: Connecting Potential and Field (2)
    • 30.2: Sources of Electric Potential (1)
    • 30.3: Finding the Electric Field from the Potential (3)
    • 30.4: A Conductor in Electrostatic Equilibrium
    • 30.5: Capacitance and Capacitors (4)
    • 30.6: The Energy Stored in a Capacitor (3)
    • 30.7: Dielectrics
    • 30: Problems (15)
    • 30: Challenge Problems (3)

  • Chapter 31: Current and Resistance
    • 31.1: The Electron Current (4)
    • 31.2: Creating a Current (2)
    • 31.3: Current and Current Density (5)
    • 31.4: Conductivity and Resistivity (5)
    • 31.5: Resistance and Ohm's Law (3)
    • 31: Problems (14)
    • 31: Challenge Problems (2)

  • Chapter 32: Fundamentals of Circuits
    • 32.1: Circuit Elements and Diagrams
    • 32.2: Kirchhoff's Laws and the Basic Circuit (3)
    • 32.3: Energy and Power (2)
    • 32.4: Series Resistors (2)
    • 32.5: Real Batteries (1)
    • 32.6: Parallel Resistors (3)
    • 32.7: Resistor Circuits
    • 32.8: Getting Grounded (1)
    • 32.9: RC Circuits (3)
    • 32: Problems (15)
    • 32: Challenge Problems (2)

  • Chapter 33: The Magnetic Field
    • 33.1: Magnetism
    • 33.2: The Discovery of the Magnetic Field
    • 33.3: The Source of the Magnetic Field: Moving Charges (4)
    • 33.4: The Magnetic Field of a Current (4)
    • 33.5: Magnetic Dipoles (3)
    • 33.6: Ampčre's Law and Solenoids (3)
    • 33.7: The Magnetic Force on a Moving Charge (4)
    • 33.8: Magnetic Forces on Current-Carrying Wires (3)
    • 33.9: Forces and Torques on Current Loops (1)
    • 33.10: Magnetic Properties of Matter
    • 33: Problems (21)
    • 33: Challenge Problems (3)

  • Chapter 34: Electromagnetic Induction
    • 34.1: Induced Currents
    • 34.2: Motional emf (1)
    • 34.3: Magnetic Flux (1)
    • 34.4: Lenz's Law (2)
    • 34.5: Faraday's Law (3)
    • 34.6: Induced Fields (1)
    • 34.7: Induced Currents: Three Applications
    • 34.8: Inductors (1)
    • 34.9: LC Circuits (2)
    • 34.10: LR Circuits (1)
    • 34: Problems (23)
    • 34: Challenge Problems (1)

  • Chapter 35: Electromagnetic Fields and Waves
    • 35.1: E or B? It Depends on Your Perspective (2)
    • 35.2: The Field Laws Thus Far
    • 35.3: The Displacement Current (3)
    • 35.4: Maxwell's Equations
    • 35.5: Electromagnetic Waves (2)
    • 35.6: Properties of Electromagnetic Waves (5)
    • 35.7: Polarization (3)
    • 35: Problems (17)
    • 35: Challenge Problems (1)

  • Chapter 36: AC Circuits
    • 36.1: AC Sources and Phasors (3)
    • 36.2: Capacitor Circuits (3)
    • 36.3: RC Filter Circuits (4)
    • 36.4: Inductor Circuits (4)
    • 36.5: The Series RLC Circuit (1)
    • 36.6: Power in AC Circuits (3)
    • 36: Problems (11)
    • 36: Challenge Problems (1)

  • Chapter 37: Relativity
    • 37.1: Relativity: What's It All About?
    • 37.2: Galilean Relativity (2)
    • 37.3: Einstein's Principle of Relativity (2)
    • 37.4: Events and Measurements
    • 37.5: The Relativity of Simultaneity (3)
    • 37.6: Time Dilation (2)
    • 37.7: Length Contraction (4)
    • 37.8: The Lorentz Transformations (3)
    • 37.9: Relativistic Momentum (1)
    • 37.10: Relativistic Energy (4)
    • 37: Problems (16)
    • 37: Challenge Problems (2)

  • Chapter 38: The End of Classical Physics
    • 38.1: Physics in the 1800s
    • 38.2: Faraday
    • 38.3: Cathode Rays
    • 38.4: J.J. Thomson and the Discovery of the Electron (3)
    • 38.5: Millikan and the Fundamental Unit of Charge (2)
    • 38.6: Rutherford and the Discovery of the Nucleus
    • 38.7: Into the Nucleus (7)
    • 38.8: The Emission and Absorption of Light (2)
    • 38.9: Classical Physics at the Limit
    • 38: Problems (11)
    • 38: Challenge Problems

  • Chapter 39: Quantization
    • 39.1: The Photoelectric Effect
    • 39.2: Einstein's Explanation (5)
    • 39.3: Photons (4)
    • 39.4: Matter Waves and Energy Quantization (2)
    • 39.5: Bohr's Model of Atomic Quantization (2)
    • 39.6: The Bohr Hydrogen Atom (2)
    • 39.7: The Hydrogen Spectrum (1)
    • 39: Problems (11)
    • 39: Challenge Problems

  • Chapter 40: Wave Functions and Uncertainty
    • 40.1: Waves, Particles, and the Double-Slit Experiment
    • 40.2: Connecting the Wave and Photon Views
    • 40.3: The Wave Function (2)
    • 40.4: Normalization (3)
    • 40.5: Wave Packets (1)
    • 40.6: The Heisenberg Uncertainty Principle (2)
    • 40: Problems (13)
    • 40: Challenge Problems

  • Chapter 41: One-Dimensional Quantum Mechanics
    • 41.1: Schrödinger's Equation: The Law of Psi
    • 41.2: Solving the Schrödinger Equation
    • 41.3: A Particle in a Rigid Box: Energies and Wave Functions (4)
    • 41.4: A Particle in a Rigid Box: Interpreting the Solution
    • 41.5: The Correspondence Principle
    • 41.6: Finite Potential Wells (3)
    • 41.7: Wave-Function Shapes
    • 41.8: The Quantum Harmonic Oscillator (4)
    • 41.9: More Quantum Models
    • 41.10: Quantum-Mechanical Tunneling (2)
    • 41: Problems (6)
    • 41: Challenge Problems

  • Chapter 42: Atomic Physics
    • 42.1: The Hydrogen Atom: Angular Momentum and Energy (4)
    • 42.2: The Hydrogen Atom: Wave Functions and Probabilities
    • 42.3: The Electron's Spin (1)
    • 42.4: Multielectron Atoms
    • 42.5: The Periodic Table of the Elements (2)
    • 42.6: Excited States and Spectra
    • 42.7: Lifetimes of Excited States (3)
    • 42.8: Stimulated Emission and Lasers (2)
    • 42: Problems (12)
    • 42: Challenge Problems

  • Chapter 43: Nuclear Physics
    • 43.1: Nuclear Structure (3)
    • 43.2: Nuclear Stability (4)
    • 43.3: The Strong Force (1)
    • 43.4: The Shell Model
    • 43.5: Radiation and Radioactivity (3)
    • 43.6: Nuclear Decay Mechanisms (3)
    • 43.7: Biological Applications of Nuclear Physics (2)
    • 43: Problems (7)
    • 43: Challenge Problems

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Group Quantity Questions
Chapter 1: Concepts of Motion
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Chapter 2: Kinematics in One Dimension
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Chapter 3: Vectors and Coordinate Systems
3.P 29 003 004 005 007 008 009 013 016 018 019 022 023 025 026 028 030 031 032 035 036 037 038 039 040 041 042 043 044 046
Chapter 4: Kinematics in Two Dimensions
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Chapter 5: Force and Motion
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Chapter 6: Dynamics I: Motion Along a Line
6.P 42 001 002 003 004 005 006 008 010 011 012 014 015 016 017 018 020 023 025 026 027 028 029 031 032 033 035 036 037 038 039 040 041 043 046 047 049 051 056 061 070 071 074
Chapter 7: Newton's Third Law
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Chapter 8: Dynamics II: Motion in a Plane
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Chapter 9: Impulse and Momentum
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Chapter 10: Energy
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Chapter 11: Work
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Chapter 12: Rotation of a Rigid Body
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Chapter 13: Newton's Theory of Gravity
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Chapter 14: Oscillations
14.P 26 003 005 011 013 015 016 018 019 026 027 030 034 036 038 042 043 047 049 050 051 052 054 055 061 069 078
Chapter 15: Fluids and Elasticity
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Chapter 16: A Macroscopic Description of Matter
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Chapter 17: Work, Heat, and the First Law of Thermodynamics
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Chapter 18: The Micro-Macro Connection
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Chapter 19: Heat Engines and Refrigerators
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Chapter 20: Traveling Waves
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Chapter 21: Superposition
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Chapter 22: Wave Optics
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Chapter 23: Ray Optics
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Chapter 24: Optical Instruments
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Chapter 25: Modern Optics and Matter Waves
25.P 26 001 003 004 005 006 007 008 009 010 013 015 016 017 018 020 021 022 023 026 028 029 030 031 032 033 034
Chapter 26: Electric Charges and Forces
26.P 26 003 005 013 015 017 020 023 025 034 035 036 037 039 041 043 045 048 049 055 057 060 061 062 064 067 075
Chapter 27: The Electric Field
27.P 34 002 004 005 006 007 009 010 011 013 015 016 018 021 023 024 025 026 029 031 039 040 041 043 046 048 051 052 053 055 056 058 066 071 073
Chapter 28: Gauss's Law
28.P 29 004 006 008 009 011 013 014 019 020 022 023 024 026 027 029 030 031 033 035 036 038 039 040 041 043 047 049 051 052
Chapter 29: The Electric Potential
29.P 30 001 002 005 006 008 009 010 015 016 020 023 024 026 030 034 036 039 042 045 047 049 051 059 060 062 065 069 077 078 083
Chapter 30: Potential and Field
30.P 31 002 004 006 010 012 013 017 023 024 027 028 031 032 036 041 045 047 050 059 061 062 064 067 068 069 071 072 073 082 085 086
Chapter 31: Current and Resistance
31.P 35 001 002 003 005 006 008 011 012 013 017 019 021 022 023 025 027 032 034 038 040 042 043 045 047 050 052 057 059 060 062 063 064 066 069 073
Chapter 32: Fundamentals of Circuits
32.P 32 003 004 006 008 011 014 015 017 021 022 023 027 031 033 035 037 042 044 045 048 051 055 057 061 062 063 064 065 071 074 075 076
Chapter 33: The Magnetic Field
33.P 46 002 005 006 007 010 011 013 014 015 016 018 021 023 024 026 028 030 033 034 035 036 041 042 043 046 047 048 053 054 057 058 059 061 062 064 066 067 068 069 070 071 073 076 078 079 081
Chapter 34: Electromagnetic Induction
34.P 36 002 004 009 010 011 012 014 017 019 023 024 026 027 030 034 039 040 041 043 046 047 048 049 050 051 052 053 054 055 063 065 066 076 078 079 082
Chapter 35: Electromagnetic Fields and Waves
35.P 33 002 004 006 010 011 012 014 016 020 021 022 023 024 026 027 028 029 031 033 035 036 038 040 041 042 043 047 048 050 054 055 056 060
Chapter 36: AC Circuits
36.P 30 001 002 006 007 008 010 012 014 015 016 018 020 021 022 028 030 032 034 038 040 042 043 048 050 052 054 055 060 061 067
Chapter 37: Relativity
37.P 39 002 004 007 008 010 014 015 016 020 022 023 024 026 028 029 033 034 038 039 040 042 044 046 048 049 050 051 054 056 057 059 060 062 066 068 071 073 077 078
Chapter 38: The End of Classical Physics
38.P 25 001 002 003 004 006 007 008 009 010 013 015 018 021 022 026 027 029 031 032 033 034 041 042 043 044
Chapter 39: Quantization
39.P 27 001 002 003 004 007 008 010 011 013 014 018 020 021 025 027 030 034 038 040 042 044 045 046 047 049 051 057
Chapter 40: Wave Functions and Uncertainty
40.P 21 011 013 014 015 017 018 024 025 026 027 028 031 034 035 036 037 038 039 042 043 045
Chapter 41: One-Dimensional Quantum Mechanics
41.P 19 001 002 003 004 008 009 010 015 016 018 019 020 021 022 026 028 031 039 040
Chapter 42: Atomic Physics
42.P 24 001 002 003 004 007 008 010 016 017 018 021 023 026 027 028 029 039 040 043 045 046 047 049 050
Chapter 43: Nuclear Physics
43.P 23 001 003 007 010 012 014 016 019 025 026 027 029 030 032 036 038 040 052 053 055 057 059 064
Total 1289