,
,PhET SIMULATIONS
Available in the Pearson eText and in the Study Area of MasteringPhysics
Extended Edition includes Chapters 1–44. Standard Edition includes Chapters 1–37.
Three-volume edition: Volume 1 includes Chapters 1–20, Volume 2 includes Chapters 21–37,
and Volume 3 includes Chapters 37–44.
Section Page Section Page
1.6 Estimation 10 25.6 Conductivity 838
1.7 Vector Addition 13 26.4 * Circuit Construction Kit (AC+DC), *Circuit
2.4 * Forces in 1 Dimension 47 Construction Kit (DC Only) 866
2.4 * The Moving Man 49 27.3 Magnet and Compass, Magnets and
2.5 Lunar Lander 52 Electromagnets 891
3.2 Maze Game 76 28.5 Faraday’s Electromagnetic Lab, Magnets
3.3 * Projectile Motion 79 and Electromagnets 933
3.4 Ladybug Revolution, Motion in 2D 87 29.2 Faraday’s Electromagnetic Lab, Faraday’s
5.2 Lunar Lander 146 Law, Generator 962
5.3 Forces in 1 Dimension, Friction, *The Ramp 149 31.3 * Circuit Construction Kit (AC+DC),
6.2 * The Ramp 181 Faraday’s Electromagnetic Lab 1031
6.3 Molecular Motors, Stretching DNA 188 32.3 Radio Waves & Electromagnetic Fields 1061
7.3 * The Ramp 222 32.5 Microwaves 1070
7.5 * Energy Skate Park 229 34.4 * Geometric Optics 1131
9.3 Ladybug Revolution 286 34.6 Color Vision 1142
10.6 Torque 326 35.2 * Wave Interference 1168
12.3 Balloons & Buoyancy 380 36.2 * Wave Interference 1192
13.2 Lunar Lander 406 38.1 Photoelectric Effect 1262
13.4 My Solar System 412 38.4 Fourier: Making Waves, Quantum Wave
14.2 Motion in 2D 443 Interference 1274
14.3 * Masses & Springs 446 39.2 Davisson-Germer: Electron Diffraction 1287
14.5 * Pendulum Lab 453 39.2 Rutherford Scattering 1294
15.8 Fourier: Making Waves, Waves on a String 495 39.3 Models of the Hydrogen Atom 1297
16.6 Sound, Wave Interference 529 39.3 Neon Lights and Other Discharge Lamps 1304
17.6 States of Matter 566 39.4 Lasers 1307
17.7 The Greenhouse Effect 570 39.5 Blackbody Spectrum, The Greenhouse
18.3 Balloons & Buoyancy, Friction, Effect 1310
Gas Properties 599 40.1 Fourier: Making Waves 1328
18.6 States of Matter 612 40.1 Quantum Tunneling and Wave Packets 1337
21.2 Balloons and Static Electricity, 40.3 Double Wells & Covalent Bonds, Quantum
John Travoltage 691 Bound States 1343
21.6 * Charges and Fields, Electric Field of Dreams, 40.4 Quantum Tunneling and Wave Packets 1347
Electric Field Hockey 708 41.5 Stern-Gerlach Experiment 1383
21.7 Microwaves 711 42.1 Double Wells and Covalent Bonds 1406
23.2 * Charges & Fields 761 42.2 The Greenhouse Effect 1409
24.5 Molecular Motors, Optical Tweezers and 42.4 Band Structure, Conductivity 1417
Applications, Stretching DNA 806 42.6 Semiconductors, Conductivity 1422
25.3 Resistance in a Wire 825 43.1 Simplified MRI 1444
25.4 Battery Voltage, Signal Circuit 829 43.3 Alpha Decay 1450
25.5 Battery-Resistor Circuit, *Circuit Construction 43.7 Nuclear Fission 1464
Kit (AC+DC), *Circuit Construction Kit
(DC Only), Ohm’s Law 834
*Indicates an associated tutorial available in the MasteringPhysics Item Library.
, ACTIVPHYSICS ONLINE™
ACTIVITIES
www.masteringphysics.com
1.1 Analyzing Motion Using Diagrams 7.6 Rotational Inertia 11.12 Electric Potential, Field, and Force
1.2 Analyzing Motion Using Graphs 7.7 Rotational Kinematics 11.13 Electrical Potential Energy and Potential
1.3 Predicting Motion from Graphs 7.8 Rotoride–Dynamics Approach 12.1 DC Series Circuits (Qualitative)
1.4 Predicting Motion from Equations 7.9 Falling Ladder 12.2 DC Parallel Circuits
1.5 Problem-Solving Strategies for 7.10 Woman and Flywheel Elevator–Dynamics 12.3 DC Circuit Puzzles
Kinematics Approach 12.4 Using Ammeters and Voltmeters
1.6 Skier Races Downhill 7.11 Race Between a Block and a Disk 12.5 Using Kirchhoff’s Laws
1.7 Balloonist Drops Lemonade 7.12 Woman and Flywheel Elevator–Energy 12.6 Capacitance
1.8 Seat Belts Save Lives Approach 12.7 Series and Parallel Capacitors
1.9 Screeching to a Halt 7.13 Rotoride–Energy Approach 12.8 RC Circuit Time Constants
1.10 Pole-Vaulter Lands 7.14 Ball Hits Bat 13.1 Magnetic Field of a Wire
1.11 Car Starts, Then Stops 8.1 Characteristics of a Gas 13.2 Magnetic Field of a Loop
1.12 Solving Two-Vehicle Problems 8.2 Maxwell-Boltzmann 13.3 Magnetic Field of a Solenoid
1.13 Car Catches Truck Distribution–Conceptual Analysis 13.4 Magnetic Force on a Particle
1.14 Avoiding a Rear-End Collision 8.3 Maxwell-Boltzmann 13.5 Magnetic Force on a Wire
2.1.1 Force Magnitudes Distribution–Quantitative Analysis 13.6 Magnetic Torque on a Loop
2.1.2 Skydiver 8.4 State Variables and Ideal Gas Law 13.7 Mass Spectrometer
2.1.3 Tension Change 8.5 Work Done By a Gas 13.8 Velocity Selector
2.1.4 Sliding on an Incline 8.6 Heat, Internal Energy, and First Law 13.9 Electromagnetic Induction
2.1.5 Car Race of Thermodynamics 13.10 Motional emf
2.2 Lifting a Crate 8.7 Heat Capacity 14.1 The RL Circuit
2.3 Lowering a Crate 8.8 Isochoric Process 14.2 The RLC Oscillator
2.4 Rocket Blasts Off 8.9 Isobaric Process 14.3 The Driven Oscillator
2.5 Truck Pulls Crate 8.10 Isothermal Process 15.1 Reflection and Refraction
2.6 Pushing a Crate Up a Wall 8.11 Adiabatic Process 15.2 Total Internal Reflection
2.7 Skier Goes Down a Slope 8.12 Cyclic Process–Strategies 15.3 Refraction Applications
2.8 Skier and Rope Tow 8.13 Cyclic Process–Problems 15.4 Plane Mirrors
2.9 Pole-Vaulter Vaults 8.14 Carnot Cycle 15.5 Spherical Mirrors: Ray Diagrams
2.10 Truck Pulls Two Crates 9.1 Position Graphs and Equations 15.6 Spherical Mirror: The Mirror Equation
2.11 Modified Atwood Machine 9.2 Describing Vibrational Motion 15.7 Spherical Mirror: Linear Magnification
3.1 Solving Projectile Motion Problems 9.3 Vibrational Energy 15.8 Spherical Mirror: Problems
3.2 Two Balls Falling 9.4 Two Ways to Weigh Young Tarzan 15.9 Thin-Lens Ray Diagrams
3.3 Changing the x-Velocity 9.5 Ape Drops Tarzan 15.10 Converging Lens Problems
3.4 Projectile x- and y-Accelerations 9.6 Releasing a Vibrating Skier I 15.11 Diverging Lens Problems
3.5 Initial Velocity Components 9.7 Releasing a Vibrating Skier II 15.12 Two-Lens Optical Systems
3.6 Target Practice I 9.8 One-and Two-Spring Vibrating Systems 16.1 Two-Source Interference: Introduction
3.7 Target Practice II 9.9 Vibro-Ride
4.1 Magnitude of Centripetal Acceleration 16.2 Two-Source Interference: Qualitative
9.10 Pendulum Frequency Questions
4.2 Circular Motion Problem Solving 9.11 Risky Pendulum Walk 16.3 Two-Source Interference: Problems
4.3 Cart Goes Over Circular Path 9.12 Physical Pendulum
4.4 Ball Swings on a String 16.4 The Grating: Introduction and Qualitative
10.1 Properties of Mechanical Waves Questions
4.5 Car Circles a Track 10.2 Speed of Waves on a String
4.6 Satellites Orbit 16.5 The Grating: Problems
10.3 Speed of Sound in a Gas 16.6 Single-Slit Diffraction
5.1 Work Calculations
10.4 Standing Waves on Strings 16.7 Circular Hole Diffraction
5.2 Upward-Moving Elevator Stops
10.5 Tuning a Stringed Instrument: 16.8 Resolving Power
5.3 Stopping a Downward-Moving Elevator
Standing Waves 16.9 Polarization
5.4 Inverse Bungee Jumper
10.6 String Mass and Standing Waves 17.1 Relativity of Time
5.5 Spring-Launched Bowler
10.7 Beats and Beat Frequency 17.2 Relativity of Length
5.6 Skier Speed
10.8 Doppler Effect: Conceptual Introduction 17.3 Photoelectric Effect
5.7 Modified Atwood Machine
10.9 Doppler Effect: Problems 17.4 Compton Scattering
6.1 Momentum and Energy Change
6.2 Collisions and Elasticity 10.10 Complex Waves: Fourier Analysis 17.5 Electron Interference
6.3 Momentum Conservation and Collisions 11.1 Electric Force: Coulomb’s Law 17.6 Uncertainty Principle
6.4 Collision Problems 11.2 Electric Force: Superposition Principle 17.7 Wave Packets
6.5 Car Collision: Two Dimensions 11.3 Electric Force: Superposition Principle 18.1 The Bohr Model
6.6 Saving an Astronaut (Quantitative) 18.2 Spectroscopy
6.7 Explosion Problems 11.4 Electric Field: Point Charge 18.3 The Laser
6.8 Skier and Cart 11.5 Electric Field Due to a Dipole 19.1 Particle Scattering
6.9 Pendulum Bashes Box 11.6 Electric Field: Problems 19.2 Nuclear Binding Energy
6.10 Pendulum Person-Projectile Bowling 11.7 Electric Flux 19.3 Fusion
7.1 Calculating Torques 11.8 Gauss’s Law 19.4 Radioactivity
7.2 A Tilted Beam: Torques and Equilibrium 11.9 Motion of a Charge in an Electric Field: 19.5 Particle Physics
7.3 Arm Levers Introduction 20.1 Potential Energy Diagrams
7.4 Two Painters on a Beam 11.10 Motion in an Electric Field: Problems 20.2 Particle in a Box
7.5 Lecturing from a Beam 11.11 Electric Potential: Qualitative 20.3 Potential Wells
Introduction 20.4 Potential Barriers
,PhET SIMULATIONS
Available in the Pearson eText and in the Study Area of MasteringPhysics
Extended Edition includes Chapters 1–44. Standard Edition includes Chapters 1–37.
Three-volume edition: Volume 1 includes Chapters 1–20, Volume 2 includes Chapters 21–37,
and Volume 3 includes Chapters 37–44.
Section Page Section Page
1.6 Estimation 10 25.6 Conductivity 838
1.7 Vector Addition 13 26.4 * Circuit Construction Kit (AC+DC), *Circuit
2.4 * Forces in 1 Dimension 47 Construction Kit (DC Only) 866
2.4 * The Moving Man 49 27.3 Magnet and Compass, Magnets and
2.5 Lunar Lander 52 Electromagnets 891
3.2 Maze Game 76 28.5 Faraday’s Electromagnetic Lab, Magnets
3.3 * Projectile Motion 79 and Electromagnets 933
3.4 Ladybug Revolution, Motion in 2D 87 29.2 Faraday’s Electromagnetic Lab, Faraday’s
5.2 Lunar Lander 146 Law, Generator 962
5.3 Forces in 1 Dimension, Friction, *The Ramp 149 31.3 * Circuit Construction Kit (AC+DC),
6.2 * The Ramp 181 Faraday’s Electromagnetic Lab 1031
6.3 Molecular Motors, Stretching DNA 188 32.3 Radio Waves & Electromagnetic Fields 1061
7.3 * The Ramp 222 32.5 Microwaves 1070
7.5 * Energy Skate Park 229 34.4 * Geometric Optics 1131
9.3 Ladybug Revolution 286 34.6 Color Vision 1142
10.6 Torque 326 35.2 * Wave Interference 1168
12.3 Balloons & Buoyancy 380 36.2 * Wave Interference 1192
13.2 Lunar Lander 406 38.1 Photoelectric Effect 1262
13.4 My Solar System 412 38.4 Fourier: Making Waves, Quantum Wave
14.2 Motion in 2D 443 Interference 1274
14.3 * Masses & Springs 446 39.2 Davisson-Germer: Electron Diffraction 1287
14.5 * Pendulum Lab 453 39.2 Rutherford Scattering 1294
15.8 Fourier: Making Waves, Waves on a String 495 39.3 Models of the Hydrogen Atom 1297
16.6 Sound, Wave Interference 529 39.3 Neon Lights and Other Discharge Lamps 1304
17.6 States of Matter 566 39.4 Lasers 1307
17.7 The Greenhouse Effect 570 39.5 Blackbody Spectrum, The Greenhouse
18.3 Balloons & Buoyancy, Friction, Effect 1310
Gas Properties 599 40.1 Fourier: Making Waves 1328
18.6 States of Matter 612 40.1 Quantum Tunneling and Wave Packets 1337
21.2 Balloons and Static Electricity, 40.3 Double Wells & Covalent Bonds, Quantum
John Travoltage 691 Bound States 1343
21.6 * Charges and Fields, Electric Field of Dreams, 40.4 Quantum Tunneling and Wave Packets 1347
Electric Field Hockey 708 41.5 Stern-Gerlach Experiment 1383
21.7 Microwaves 711 42.1 Double Wells and Covalent Bonds 1406
23.2 * Charges & Fields 761 42.2 The Greenhouse Effect 1409
24.5 Molecular Motors, Optical Tweezers and 42.4 Band Structure, Conductivity 1417
Applications, Stretching DNA 806 42.6 Semiconductors, Conductivity 1422
25.3 Resistance in a Wire 825 43.1 Simplified MRI 1444
25.4 Battery Voltage, Signal Circuit 829 43.3 Alpha Decay 1450
25.5 Battery-Resistor Circuit, *Circuit Construction 43.7 Nuclear Fission 1464
Kit (AC+DC), *Circuit Construction Kit
(DC Only), Ohm’s Law 834
*Indicates an associated tutorial available in the MasteringPhysics Item Library.
, ACTIVPHYSICS ONLINE™
ACTIVITIES
www.masteringphysics.com
1.1 Analyzing Motion Using Diagrams 7.6 Rotational Inertia 11.12 Electric Potential, Field, and Force
1.2 Analyzing Motion Using Graphs 7.7 Rotational Kinematics 11.13 Electrical Potential Energy and Potential
1.3 Predicting Motion from Graphs 7.8 Rotoride–Dynamics Approach 12.1 DC Series Circuits (Qualitative)
1.4 Predicting Motion from Equations 7.9 Falling Ladder 12.2 DC Parallel Circuits
1.5 Problem-Solving Strategies for 7.10 Woman and Flywheel Elevator–Dynamics 12.3 DC Circuit Puzzles
Kinematics Approach 12.4 Using Ammeters and Voltmeters
1.6 Skier Races Downhill 7.11 Race Between a Block and a Disk 12.5 Using Kirchhoff’s Laws
1.7 Balloonist Drops Lemonade 7.12 Woman and Flywheel Elevator–Energy 12.6 Capacitance
1.8 Seat Belts Save Lives Approach 12.7 Series and Parallel Capacitors
1.9 Screeching to a Halt 7.13 Rotoride–Energy Approach 12.8 RC Circuit Time Constants
1.10 Pole-Vaulter Lands 7.14 Ball Hits Bat 13.1 Magnetic Field of a Wire
1.11 Car Starts, Then Stops 8.1 Characteristics of a Gas 13.2 Magnetic Field of a Loop
1.12 Solving Two-Vehicle Problems 8.2 Maxwell-Boltzmann 13.3 Magnetic Field of a Solenoid
1.13 Car Catches Truck Distribution–Conceptual Analysis 13.4 Magnetic Force on a Particle
1.14 Avoiding a Rear-End Collision 8.3 Maxwell-Boltzmann 13.5 Magnetic Force on a Wire
2.1.1 Force Magnitudes Distribution–Quantitative Analysis 13.6 Magnetic Torque on a Loop
2.1.2 Skydiver 8.4 State Variables and Ideal Gas Law 13.7 Mass Spectrometer
2.1.3 Tension Change 8.5 Work Done By a Gas 13.8 Velocity Selector
2.1.4 Sliding on an Incline 8.6 Heat, Internal Energy, and First Law 13.9 Electromagnetic Induction
2.1.5 Car Race of Thermodynamics 13.10 Motional emf
2.2 Lifting a Crate 8.7 Heat Capacity 14.1 The RL Circuit
2.3 Lowering a Crate 8.8 Isochoric Process 14.2 The RLC Oscillator
2.4 Rocket Blasts Off 8.9 Isobaric Process 14.3 The Driven Oscillator
2.5 Truck Pulls Crate 8.10 Isothermal Process 15.1 Reflection and Refraction
2.6 Pushing a Crate Up a Wall 8.11 Adiabatic Process 15.2 Total Internal Reflection
2.7 Skier Goes Down a Slope 8.12 Cyclic Process–Strategies 15.3 Refraction Applications
2.8 Skier and Rope Tow 8.13 Cyclic Process–Problems 15.4 Plane Mirrors
2.9 Pole-Vaulter Vaults 8.14 Carnot Cycle 15.5 Spherical Mirrors: Ray Diagrams
2.10 Truck Pulls Two Crates 9.1 Position Graphs and Equations 15.6 Spherical Mirror: The Mirror Equation
2.11 Modified Atwood Machine 9.2 Describing Vibrational Motion 15.7 Spherical Mirror: Linear Magnification
3.1 Solving Projectile Motion Problems 9.3 Vibrational Energy 15.8 Spherical Mirror: Problems
3.2 Two Balls Falling 9.4 Two Ways to Weigh Young Tarzan 15.9 Thin-Lens Ray Diagrams
3.3 Changing the x-Velocity 9.5 Ape Drops Tarzan 15.10 Converging Lens Problems
3.4 Projectile x- and y-Accelerations 9.6 Releasing a Vibrating Skier I 15.11 Diverging Lens Problems
3.5 Initial Velocity Components 9.7 Releasing a Vibrating Skier II 15.12 Two-Lens Optical Systems
3.6 Target Practice I 9.8 One-and Two-Spring Vibrating Systems 16.1 Two-Source Interference: Introduction
3.7 Target Practice II 9.9 Vibro-Ride
4.1 Magnitude of Centripetal Acceleration 16.2 Two-Source Interference: Qualitative
9.10 Pendulum Frequency Questions
4.2 Circular Motion Problem Solving 9.11 Risky Pendulum Walk 16.3 Two-Source Interference: Problems
4.3 Cart Goes Over Circular Path 9.12 Physical Pendulum
4.4 Ball Swings on a String 16.4 The Grating: Introduction and Qualitative
10.1 Properties of Mechanical Waves Questions
4.5 Car Circles a Track 10.2 Speed of Waves on a String
4.6 Satellites Orbit 16.5 The Grating: Problems
10.3 Speed of Sound in a Gas 16.6 Single-Slit Diffraction
5.1 Work Calculations
10.4 Standing Waves on Strings 16.7 Circular Hole Diffraction
5.2 Upward-Moving Elevator Stops
10.5 Tuning a Stringed Instrument: 16.8 Resolving Power
5.3 Stopping a Downward-Moving Elevator
Standing Waves 16.9 Polarization
5.4 Inverse Bungee Jumper
10.6 String Mass and Standing Waves 17.1 Relativity of Time
5.5 Spring-Launched Bowler
10.7 Beats and Beat Frequency 17.2 Relativity of Length
5.6 Skier Speed
10.8 Doppler Effect: Conceptual Introduction 17.3 Photoelectric Effect
5.7 Modified Atwood Machine
10.9 Doppler Effect: Problems 17.4 Compton Scattering
6.1 Momentum and Energy Change
6.2 Collisions and Elasticity 10.10 Complex Waves: Fourier Analysis 17.5 Electron Interference
6.3 Momentum Conservation and Collisions 11.1 Electric Force: Coulomb’s Law 17.6 Uncertainty Principle
6.4 Collision Problems 11.2 Electric Force: Superposition Principle 17.7 Wave Packets
6.5 Car Collision: Two Dimensions 11.3 Electric Force: Superposition Principle 18.1 The Bohr Model
6.6 Saving an Astronaut (Quantitative) 18.2 Spectroscopy
6.7 Explosion Problems 11.4 Electric Field: Point Charge 18.3 The Laser
6.8 Skier and Cart 11.5 Electric Field Due to a Dipole 19.1 Particle Scattering
6.9 Pendulum Bashes Box 11.6 Electric Field: Problems 19.2 Nuclear Binding Energy
6.10 Pendulum Person-Projectile Bowling 11.7 Electric Flux 19.3 Fusion
7.1 Calculating Torques 11.8 Gauss’s Law 19.4 Radioactivity
7.2 A Tilted Beam: Torques and Equilibrium 11.9 Motion of a Charge in an Electric Field: 19.5 Particle Physics
7.3 Arm Levers Introduction 20.1 Potential Energy Diagrams
7.4 Two Painters on a Beam 11.10 Motion in an Electric Field: Problems 20.2 Particle in a Box
7.5 Lecturing from a Beam 11.11 Electric Potential: Qualitative 20.3 Potential Wells
Introduction 20.4 Potential Barriers
