Principles of Physics A Calculus Based Text 5th Edition by Raymond A. Serway, John W. Jewett – Ebook PDF Instand Download/DeliveryISBN: 9798214351209
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ISBN-13 : 9798214351209
Author: Raymond A. Serway, John W. Jewett
PRINCIPLES OF PHYSICS features a concise approach to traditional topics, an early introduction to modern physics, and integration of physics education research pedagogy, as well as the inclusion of contemporary topics throughout the text. This revision of PRINCIPLES OF PHYSICS also contains a new worked example format, two new Contexts features, a revised problem set based on an analysis of problem usage data from WebAssign, and a thorough revision of every piece of line art in the text.
Principles of Physics A Calculus Based Text 5th Table of contents:
Chapter 1. Introduction and Vectors
1.1. Standards of Length, Mass, and Time
Length
Mass
Time
Approximate Values for Length, Mass, and Time
1.2. Dimensional Analysis
1.3. Conversion of Units
1.4. Order-of-Magnitude Calculations
1.5. Significant Figures
1.6. Coordinate Systems
1.7. Vectors and Scalars
1.8. Some Properties of Vectors
Equality of Two Vectors
Addition
Negative of a Vector
Subtraction of Vectors
Multiplication of a Vector by a Scalar
Multiplication of Two Vectors
1.9. Components of a Vector and Unit Vectors
Unit Vectors
1.10. Modeling, Alternative Representations, and Problem-Solving Strategy
Summary
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 1.1. Standards of Length, Mass, and Time
Problems: Section 1.2. Dimensional Analysis
Problems: Section 1.3. Conversion of Units
Problems: Section 1.4. Order-of-Magnitude Calculations
Problems: Section 1.5. Significant Figures
Problems: Section 1.6. Coordinate Systems
Problems: Section 1.7 and Section 1.8
Problems: Section 1.9. Components of a Vector and Unit Vectors
Problems: Section 1.10. Modeling, Alternative Representations, and Problem-Solving Strategy
Problems: Additional Problems
Context 1. Alternative-Fuel Vehicles
Alternative-Fuel Vehicles
Chapter 2. Motion in One Dimension
2.1. Average Velocity
2.2. Instantaneous Velocity
2.3. Analysis Model: Particle under Constant Velocity
2.4. Acceleration
2.5. Motion Diagrams
2.6. Analysis Model: Particle under Constant Acceleration
2.7. Freely Falling Objects
2.8. Context Connection: Acceleration Required by Consumers
Summary
Analysis Models for Problem-Solving
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 2.1. Average Velocity
Problems: Section 2.2. Instantaneous Velocity
Problems: Section 2.3. Analysis Model: Particle under Constant Velocity
Problems: Section 2.4. Acceleration
Problems: Section 2.5. Motion Diagrams
Problems: Section 2.6. Analysis Model: Particle under Constant Acceleration
Problems: Section 2.7. Freely Falling Objects
Problems: Section 2.8. Context Connection: Acceleration Required by Consumers
Problems: Additional Problems
Chapter 3. Motion in Two Dimensions
3.1. The Position, Velocity, and Acceleration Vectors
3.2. Two-Dimensional Motion with Constant Acceleration
3.3. Projectile Motion
Horizontal Range and Maximum Height of a Projectile
3.4. Analysis Model: Particle in Uniform Circular Motion
3.5. Tangential and Radial Acceleration
3.6. Relative Velocity and Relative Acceleration
3.7. Context Connection: Lateral Acceleration of Automobiles
Summary
Analysis Model for Problem Solving
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 3.1. The Position, Velocity, and Acceleration Vectors
Problems: Section 3.2. Two-Dimensional Motion with Constant Acceleration
Problems: Section 3.3. Projectile Motion
Problems: Section 3.4. Analysis Model: Particle in Uniform Circular Motion
Problems: Section 3.5. Tangential and Radial Acceleration
Problems: Section 3.6. Relative Velocity and Relative Acceleration
Problems: Section 3.7. Context Connection: Lateral Acceleration of Automobiles
Problems: Additional Problems
Chapter 4. The Laws of Motion
4.1. The Concept of Force
4.2. Newton’s First Law
4.3. Mass
4.4. Newton’s Second Law
Unit of Force
4.5. The Gravitational Force and Weight
4.6. Newton’s Third Law
4.7. Analysis Models Using Newton’s Second Law
Analysis Model: Particle in Equilibrium
Analysis Model: Particle under a Net Force
4.8. Context Connection: Forces on Automobiles
Summary
Analysis Models for Problem Solving
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 4.3. Mass
Problems: Section 4.4. Newton’s Second Law
Problems: Section 4.5. The Gravitational Force and Weight
Problems: Section 4.6. Newton’s Third Law
Problems: Section 4.7. Analysis Models Using Newton’s Second Law
Problems: Section 4.8. Context Connection: Forces on Automobiles
Problems: Additional Problems
Chapter 5. More Applications of Newton’s Laws
5.1. Forces of Friction
5.2. Extending the Particle in Uniform Circular Motion Model
5.3. Nonuniform Circular Motion
5.4. Motion in the Presence of Velocity-Dependent Resistive Forces
Model 1: Resistive Force Proportional to Object Velocity
Model 2: Resistive Force Proportional to Object Speed Squared
5.5. The Fundamental Forces of Nature
The Gravitational Force
The Electromagnetic Force
The Strong Force
The Weak Force
The Current View of Fundamental Forces
5.6. Context Connection: Drag Coefficients of Automobiles
Summary
Analysis Model for Problem Solving
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 5.1. Forces of Friction
Problems: Section 5.2. Extending the Particle in Uniform Circular Motion Model
Problems: Section 5.3. Nonuniform Circular Motion
Problems: Section 5.4. Motion in the Presence of Velocity-Dependent Resistive Forces
Problems: Section 5.5. The Fundamental Forces of Nature
Problems: Section 5.6. Context Connection: Drag Coefficients of Automobiles
Problems: Additional Problems
Chapter 6. Energy of a System
6.1. Systems and Environments
6.2. Work Done by a Constant Force
6.3. The Scalar Product of Two Vectors
6.4. Work Done by a Varying Force
Work Done by a Spring
6.5. Kinetic Energy and the Work–Kinetic Energy Theorem
6.6. Potential Energy of a System
Elastic Potential Energy
Energy Bar Charts
6.7. Conservative and Nonconservative Forces
Conservative Forces
Nonconservative Forces
6.8. Relationship between Conservative Forces and Potential Energy
6.9. Potential Energy for Gravitational and Electric Forces
6.10. Energy Diagrams and Equilibrium of a System
6.11. Context Connection: Potential Energy in Fuels
Ethanol
Biodiesel
Natural Gas
Propane
Electric Vehicles
Summary
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 6.2. Work Done by a Constant Force
Problems: Section 6.3. The Scalar Product of Two Vectors
Problems: Section 6.4. Work Done by a Varying Force
Problems: Section 6.5. Kinetic Energy and the Work–Kinetic Energy Theorem
Problems: Section 6.6. Potential Energy of a System
Problems: Section 6.7. Conservative and Nonconservative Forces
Problems: Section 6.8. Relationship between Conservative Forces and Potential Energy
Problems: Section 6.9. Potential Energy for Gravitational and Electric Forces
Problems: Section 6.10. Energy Diagrams and Equilibrium of a System
Problems: Section 6.11. Context Connection: Potential Energy in Fuels
Problems: Additional Problems
Chapter 7. Conservation of Energy
7.1. Analysis Model: Nonisolated System (Energy)
7.2. Analysis Model: Isolated System (Energy)
7.3. Analysis Model: Nonisolated System in Steady State (Energy)
7.4. Situations Involving Kinetic Friction
7.5. Changes in Mechanical Energy for Nonconservative Forces
7.6. Power
7.7. Context Connection: Horsepower Ratings of Automobiles
Summary
Analysis Models for Problem Solving
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 7.1. Analysis Model: Nonisolated System (Energy)
Problems: Section 7.2. Analysis Model: Isolated System (Energy)
Problems: Section 7.4. Situations Involving Kinetic Friction
Problems: Section 7.5. Changes in Mechanical Energy for Nonconservative Forces
Problems: Section 7.6. Power
Problems: Section 7.7. Context Connection: Horsepower Ratings of Automobiles
Problems: Additional Problems
Context 1. CONCLUSION: Present and Future Possibilities
Present and Future Possibilities
Available Now—The Hybrid Electric Vehicle
In the Future—The Fuel Cell Vehicle
Problems
Context 2. Mission to Mars
Mission to Mars
Chapter 8. Momentum and Collisions
8.1. Linear Momentum
8.2. Analysis Model: Isolated System (Momentum)
8.3. Analysis Model: Nonisolated System (Momentum)
8.4. Collisions in One Dimension
Perfectly Inelastic Collisions
Elastic Collisions
8.5. Collisions in Two Dimensions
8.6. The Center of Mass
8.7. Motion of a System of Particles
8.8. Context Connection: Rocket Propulsion
Summary
Analysis Models for Problem Solving
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 8.1 and Section 8.2
Problems: Section 8.3. Analysis Model: Nonisolated System (Momentum)
Problems: Section 8.4. Collisions in One Dimension
Problems: Section 8.5. Collisions in Two Dimensions
Problems: Section 8.6. The Center of Mass
Problems: Section 8.7. Motion of a System of Particles
Problems: Section 8.8. Context Connection: Rocket Propulsion
Problems: Additional Problems
Chapter 9. Relativity
9.1. The Principle of Galilean Relativity
9.2. The Michelson–Morley Experiment
9.3. Einstein’s Principle of Relativity
9.4. Consequences of Special Relativity
Simultaneity and the Relativity of Time
Time Dilation
The Twin Paradox
Length Contraction
9.5. The Lorentz Transformation Equations
Lorentz Velocity Transformation
9.6. Relativistic Momentum and the Relativistic Form of Newton’s Laws
9.7. Relativistic Energy
9.8. Mass and Energy
9.9. General Relativity
9.10. Context Connection: From Mars to the Stars
Summary
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 9.1. The Principle of Galilean Relativity
Problems: Section 9.2 through Section 9.4
Problems: Section 9.5. The Lorentz Transformation Equations
Problems: Section 9.6. Relativistic Momentum and the Relativistic Form of Newton’s Laws
Problems: Section 9.7. Relativistic Energy
Problems: Section 9.8. Mass and Energy
Problems: Section 9.9. General Relativity
Problems: Section 9.10. Context Connection: From Mars to the Stars
Problems: Additional Problems
Chapter 10. Rotational Motion
10.1. Angular Position, Speed, and Acceleration
10.2. Analysis Model: Rigid Object under Constant Angular Acceleration
10.3. Relations between Rotational and Translational Quantities
10.4. Rotational Kinetic Energy
10.5. Torque and the Vector Product
10.6. Analysis Model: Rigid Object in Equilibrium
10.7. Analysis Model: Rigid Object under a Net Torque
10.8. Energy Considerations in Rotational Motion
10.9. Analysis Model: Nonisolated System (Angular Momentum)
10.10. Analysis Model: Isolated System (Angular Momentum)
10.11. Precessional Motion of Gyroscopes
10.12. Rolling Motion of Rigid Objects
10.13. Context Connection: Turning the Spacecraft
Summary
Analysis Models for Problem Solving
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 10.1. Angular Position, Speed, and Acceleration
Problems: Section 10.2. Analysis Model: Rigid Object under Constant Angular Acceleration
Problems: Section 10.3. Relations between Rotational and Translational Quantities
Problems: Section 10.4. Rotational Kinetic Energy
Problems: Section 10.5. Torque and the Vector Product
Problems: Section 10.6. Analysis Model: Rigid Object in Equilibrium
Problems: Section 10.7 and Section 10.8
Problems: Section 10.9 and Section 10.10
Problems: Section 10.11. Precessional Motion of Gyroscopes
Problems: Section 10.12. Rolling Motion of Rigid Objects
Problems: Section 10.13. Context Connection—Turning the Spacecraft
Problems: Additional Problems
Chapter 11. Gravity, Planetary Orbits, and the Hydrogen Atom
11.1. Newton’s Law of Universal Gravitation Revisited
Measurement of the Gravitational Constant
The Gravitational Field
11.2. Structural Models
11.3. Kepler’s Laws
Kepler’s First Law
Kepler’s Second Law
Kepler’s Third Law
11.4. Energy Considerations in Planetary and Satellite Motion
Escape Speed
Black Holes
11.5. Atomic Spectra and the Bohr Theory of Hydrogen
11.6. Context Connection: Changing from a Circular to an Elliptical Orbit
Summary
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 11.1. Newton’s Law of Universal Gravitation
Problems: Section 11.3. Kepler’s Laws
Problems: Section 11.4. Energy Considerations in Planetary and Satellite Motion
Problems: Section 11.5. Atomic Spectra and the Bohr Theory of Hydrogen
Problems: Section 11.6. Context Connection: Changing from a Circular to an Elliptical Orbit
Problems: Additional Problems
Context 2. CONCLUSION: A Successful Mission Plan
A Successful Mission Plan
Questions
Problems
Context 3. Earthquakes
Earthquakes
Chapter 12. Oscillatory Motion
12.1. Motion of an Object Attached to a Spring
12.2. Analysis Model: Particle in Simple Harmonic Motion
12.3. Energy of the Simple Harmonic Oscillator
12.4. The Simple Pendulum
12.5. The Physical Pendulum
12.6. Damped Oscillations
12.7. Forced Oscillations
12.8. Context Connection: Resonance in Structures
Summary
Analysis Model for Problem Solving
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 12.1. Motion of an Object Attached to a Spring
Problems: Section 12.2. Analysis Model: Particle in Simple Harmonic Motion
Problems: Section 12.3. Energy of the Simple Harmonic Oscillator
Problems: Section 12.4 and Section 12.5
Problems: Section 12.6. Damped Oscillations
Problems: Section 12.7. Forced Oscillations
Problems: Section 12.8. Context Connection: Resonance in Structures
Problems: Additional Problems
Chapter 13. Mechanical Waves
13.1. Propagation of a Disturbance
13.2. Analysis Model: Traveling Wave
The Linear Wave Equation
13.3. The Speed of Transverse Waves on Strings
13.4. Reflection and Transmission
13.5. Rate of Energy Transfer by Sinusoidal Waves on Strings
13.6. Sound Waves
13.7. The Doppler Effect
Doppler Sonography
13.8. Context Connection: Seismic Waves
Summary
Analysis Model for Problem Solving
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 13.1. Propagation of a Disturbance
Problems: Section 13.2. Analysis Model: Traveling Wave
Problems: Section 13.3. The Speed of Transverse Waves on Strings
Problems: Section 13.4. Reflection and Transmission
Problems: Section 13.5. Rate of Energy Transfer by Sinusoidal Waves on Strings
Problems: Section 13.6. Sound Waves
Problems: Section 13.7. The Doppler Effect
Problems: Section 13.8. Context Connection: Seismic Waves
Problems: Additional Problems
Chapter 14. Superposition and Standing Waves
14.1. Analysis Model: Waves in Interference
Superposition of Sinusoidal Waves
Interference of Sound Waves
14.2. Standing Waves
14.3. Analysis Model: Waves under Boundary Conditions
14.4. Standing Waves in Air Columns
14.5. Beats: Interference in Time
14.6. Nonsinusoidal Wave Patterns
14.7. The Ear and Theories of Pitch Perception
Theories of Pitch Perception
14.8. Context Connection: Building on Antinodes
Summary
Analysis Models for Problem Solving
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 14.1. Analysis Model: Waves in Interference
Problems: Section 14.2. Standing Waves
Problems: Section 14.3. Analysis Model: Waves under Boundary Conditions
Problems: Section 14.4. Standing Waves in Air Columns
Problems: Section 14.5. Beats: Interference in Time
Problems: Section 14.6. Nonsinusoidal Wave Patterns
Problems: Section 14.7. The Ear and Theories of Pitch Perception
Problems: Section 14.8. Context Connection: Building on Antinodes
Problems: Additional Problems
Context 3. CONCLUSION: Minimizing the Risk
Minimizing the Risk
Problems
Context 4. Heart Attacks
Heart Attacks
Chapter 15. Fluid Mechanics
15.1. Pressure
15.2. Variation of Pressure with Depth
15.3. Pressure Measurements
15.4. Buoyant Forces and Archimedes’s Principle
Case I: A Totally Submerged Object
Case II: A Floating Object
15.5. Fluid Dynamics
Flow Characteristics
15.6. Streamlines and the Continuity Equation for Fluids
15.7. Bernoulli’s Equation
15.8. Other Applications of Fluid Dynamics
15.9. Context Connection: Turbulent Flow of Blood
Summary
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 15.1. Pressure
Problems: Section 15.2. Variation of Pressure with Depth
Problems: Section 15.3. Pressure Measurements
Problems: Section 15.4. Buoyant Forces and Archimedes’s Principle
Problems: Section 15.5 through Section 15.7
Problems: Section 15.8. Other Applications of Fluid Dynamics
Problems: Section 15.9. Context Connection: Turbulent Flow of Blood
Problems: Additional Problems
Context 4. CONCLUSION: Detecting Atherosclerosis and Preventing Heart Attacks
Detecting Atherosclerosis and Preventing Heart Attacks
Problems
Context 5. Global Warming
Global Warming
Chapter 16. Temperature and the Kinetic Theory of Gases
16.1. Temperature and the Zeroth Law of Thermodynamics
16.2. Thermometers and Temperature Scales
The Constant-Volume Gas Thermometer and the Kelvin Scale
The Fahrenheit Scale
16.3. Thermal Expansion of Solids and Liquids
The Unusual Behavior of Water
16.4. Macroscopic Description of an Ideal Gas
16.5. The Kinetic Theory of Gases
Molecular Interpretation of the Pressure of an Ideal Gas
Molecular Interpretation of the Temperature of an Ideal Gas
16.6. Distribution of Molecular Speeds
16.7. Context Connection: The Atmospheric Lapse Rate
Summary
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 16.2. Thermometers and Temperature Scales
Problems: Section 16.3. Thermal Expansion of Solids and Liquids
Problems: Section 16.4. Macroscopic Description of an Ideal Gas
Problems: Section 16.5. The Kinetic Theory of Gases
Problems: Section 16.6. Distribution of Molecular Speeds
Problems: Section 16.7. Context Connection: The Atmospheric Lapse Rate
Problems: Additional Problems
Chapter 17. Energy in Thermal Processes: The First Law of Thermodynamics
17.1. Heat and Internal Energy
Units of Heat
17.2. Specific Heat
Calorimetry
17.3. Latent Heat
17.4. Work in Thermodynamic Processes
17.5. The First Law of Thermodynamics
17.6. Some Applications of the First Law of Thermodynamics
17.7. Molar Specific Heats of Ideal Gases
17.8. Adiabatic Processes for an Ideal Gas
17.9. Molar Specific Heats and the Equipartition of Energy
A Hint of Energy Quantization
17.10. Energy Transfer Mechanisms in Thermal Processes
Conduction
Convection
Radiation
17.11. Context Connection: Energy Balance for the Earth
Summary
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 17.1. Heat and Internal Energy
Problems: Section 17.2. Specific Heat
Problems: Section 17.3. Latent Heat
Problems: Section 17.4. Work in Thermodynamic Processes
Problems: Section 17.5. The First Law of Thermodynamics
Problems: Section 17.6. Some Applications of the First Law of Thermodynamics
Problems: Section 17.7. Molar Specific Heats of Ideal Gases
Problems: Section 17.8. Adiabatic Processes for an Ideal Gas
Problems: Section 17.9. Molar Specific Heats and the Equipartition of Energy
Problems: Section 17.10. Energy Transfer Mechanisms in Thermal Processes
Problems: Section 17.11. Context Connection: Energy Balance for the Earth
Problems: Additional Problems
Chapter 18. Heat Engines, Entropy, and the Second Law of Thermodynamics
18.1. Heat Engines and the Second Law of Thermodynamics
18.2. Reversible and Irreversible Processes
18.3. The Carnot Engine
18.4. Heat Pumps and Refrigerators
18.5. An Alternative Statement of the Second Law
18.6. Entropy
18.7. Entropy and the Second Law of Thermodynamics
18.8. Entropy Changes in Irreversible Processes
Entropy Changes in a Free Expansion
18.9. Context Connection: The Atmosphere as a Heat Engine
Summary
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 18.1. Heat Engines and the Second Law of Thermodynamics
Problems: Section 18.2 and Section 18.3
Problems: Section 18.4. Heat Pumps and Refrigerators
Problems: Section 18.6 and Section 18.7
Problems: Section 18.8. Entropy Changes in Irreversible Processes
Problems: Section 18.9. Context Connection: The Atmosphere as a Heat Engine
Problems: Additional Problems
Context 5. CONCLUSION: Predicting the Earth’s Surface Temperature
Predicting the Earth’s Surface Temperature
Modeling the Atmosphere
Problems
Context 6. Lightning
Lightning
Chapter 19. Electric Forces and Electric Fields
19.1. Historical Overview
19.2. Properties of Electric Charges
19.3. Insulators and Conductors
Charging by Induction
19.4. Coulomb’s Law
19.5. Electric Fields
Electric Field Due to Continuous Charge Distributions
19.6. Electric Field Lines
19.7. Motion of Charged Particles in a Uniform Electric Field
19.8. Electric Flux
19.9. Gauss’s Law
19.10. Application of Gauss’s Law to Various Charge Distributions
19.11. Conductors in Electrostatic Equilibrium
19.12. Context Connection: The Atmospheric Electric Field
Transient Luminous Events
Summary
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 19.2. Properties of Electric Charges
Problems: Section 19.4. Coulomb’s Law
Problems: Section 19.5. Electric Fields
Problems: Section 19.6. Electric Field Lines
Problems: Section 19.7. Motion of Charged Particles in a Uniform Electric Field
Problems: Section 19.8. Electric Flux
Problems: Section 19.9. Gauss’s Law
Problems: Section 19.10. Application of Gauss’s Law to Various Charge Distributions
Problems: Section 19.11. Conductors in Electrostatic Equilibrium
Problems: Section 19.12. Context Connection: The Atmospheric Electric Field
Problems: Additional Problems
Chapter 20. Electric Potential and Capacitance
20.1. Electric Potential and Potential Difference
20.2. Potential Difference in a Uniform Electric Field
20.3. Electric Potential and Potential Energy Due to Point Charges
20.4. Obtaining the Value of the Electric Field from the Electric Potential
20.5. Electric Potential Due to Continuous Charge Distributions
20.6. Electric Potential Due to a Charged Conductor
A Cavity within a Conductor
20.7. Capacitance
The Parallel-Plate Capacitor
The Cylindrical Capacitor
20.8. Combinations of Capacitors
Parallel Combination
Series Combination
20.9. Energy Stored in a Charged Capacitor
20.10. Capacitors with Dielectrics
Types of Capacitors
20.11. Context Connection: The Atmosphere as a Capacitor
Summary
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 20.1. Electric Potential and Potential Difference
Problems: Section 20.2. Potential Difference in a Uniform Electric Field
Problems: Section 20.3. Electric Potential and Potential Energy Due to Point Charges
Problems: Section 20.4. Obtaining the Value of the Electric Field from the Electric Potential
Problems: Section 20.5. Electric Potential Due to Continuous Charge Distributions
Problems: Section 20.6. Electric Potential Due to a Charged Conductor
Problems: Section 20.7. Capacitance
Problems: Section 20.8. Combinations of Capacitors
Problems: Section 20.9. Energy Stored in a Charged Capacitor
Problems: Section 20.10. Capacitors with Dielectrics
Problems: Section 20.11. Context Connection: The Atmosphere as a Capacitor
Problems: Additional Problems
Chapter 21. Current and Direct Current Circuits
21.1. Electric Current
21.2. Resistance and Ohm’s Law
Change in Resistivity with Temperature
21.3. Superconductors
21.4. A Model for Electrical Conduction
21.5. Energy and Power in Electric Circuits
21.6. Sources of emf
21.7. Resistors in Series and Parallel
21.8. Kirchhoff’s Rules
21.9. RC Circuits
Charging a Capacitor
Discharging a Capacitor
21.10. Context Connection: The Atmosphere as a Conductor
Summary
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 21.1. Electric Current
Problems: Section 21.2. Resistance and Ohm’s Law
Problems: Section 21.4. A Model for Electrical Conduction
Problems: Section 21.5. Energy and Power in Electric Circuits
Problems: Section 21.6. Sources of emf
Problems: Section 21.7. Resistors in Series and Parallel
Problems: Section 21.8. Kirchhoff’s Rules
Problems: Section 21.9. RC Circuits
Problems: Section 21.10. Context Connection: The Atmosphere as a Conductor
Problems: Additional Problems
Context 6. CONCLUSION: Determining the Number of Lightning Strikes
Determining the Number of Lightning Strikes
The Atmospheric Capacitor Model
Problems
Context 7. Magnetism in Medicine
Magnetism in Medicine
Chapter 22. Magnetic Forces and Magnetic Fields
22.1. Historical Overview
22.2. The Magnetic Field
22.3. Motion of a Charged Particle in a Uniform Magnetic Field
22.4. Applications Involving Charged Particles Moving in a Magnetic Field
Velocity Selector
The Mass Spectrometer
The Cyclotron
22.5. Magnetic Force on a Current-Carrying Conductor
22.6. Torque on a Current Loop in a Uniform Magnetic Field
22.7. The Biot–Savart Law
22.8. The Magnetic Force between Two Parallel Conductors
22.9. Ampère’s Law
22.10. The Magnetic Field of a Solenoid
22.11. Magnetism in Matter
Ferromagnetic Materials
22.12. Context Connection: Remote Magnetic Navigation for Cardiac Catheter Ablation Procedures
Summary
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 22.2. The Magnetic Field
Problems: Section 22.3. Motion of a Charged Particle in a Uniform Magnetic Field
Problems: Section 22.4. Applications Involving Charged Particles Moving in a Magnetic Field
Problems: Section 22.5. Magnetic Force on a Current-Carrying Conductor
Problems: Section 22.6. Torque on a Current Loop in a Uniform Magnetic Field
Problems: Section 22.7. The Biot–Savart Law
Problems: Section 22.8. The Magnetic Force between Two Parallel Conductors
Problems: Section 22.9. Ampère’s Law
Problems: Section 22.10. The Magnetic Field of a Solenoid
Problems: Section 22.11. Magnetism in Matter
Problems: Section 22.12. Context Connection: Remote Magnetic Navigation for Cardiac Catheter Ablation Procedures
Problems: Additional Problems
Chapter 23. Faraday’s Law and Inductance
23.1. Faraday’s Law of Induction
23.2. Motional emf
The Alternating-Current Generator
23.3. Lenz’s Law
23.4. Induced emfs and Electric Fields
23.5. Inductance
23.6. RL Circuits
23.7. Energy Stored in a Magnetic Field
23.8. Context Connection: The Use of Transcranial Magnetic Stimulation in Depression
Summary
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 23.1. Faraday’s Law of Induction
Problems: Section 23.2 and Section 23.3
Problems: Section 23.4. Induced emfs and Electric Fields
Problems: Section 23.5. Inductance
Problems: Section 23.6. RL Circuits
Problems: Section 23.7. Energy Stored in a Magnetic Field
Problems: Section 23.8. Context Connection: The Use of Transcranial Magnetic Stimulation in Depression
Problems: Additional Problems
Context 7. CONCLUSION: Nuclear Magnetic Resonance and Magnetic Resonance Imaging
Nuclear Magnetic Resonance and Magnetic Resonance Imaging
Problems
Context 8. Lasers
Lasers
Chapter 24. Electromagnetic Waves
24.1. Displacement Current and the Generalized Form of Ampère’s Law
24.2. Maxwell’s Equations and Hertz’s Discoveries
24.3. Electromagnetic Waves
Doppler Effect for Light
24.4. Energy Carried by Electromagnetic Waves
24.5. Momentum and Radiation Pressure
Space Sailing
24.6. The Spectrum of Electromagnetic Waves
24.7. Polarization of Light Waves
24.8. Context Connection: The Special Properties of Laser Light
Applications
Summary
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 24.1. Displacement Current and the Generalized Form of Ampère’s Law
Problems: Section 24.2. Maxwell’s Equations and Hertz’s Discoveries
Problems: Section 24.3. Electromagnetic Waves
Problems: Section 24.4. Energy Carried by Electromagnetic Waves
Problems: Section 24.5. Momentum and Radiation Pressure
Problems: Section 24.6. The Spectrum of Electromagnetic Waves
Problems: Section 24.7. Polarization of Light Waves
Problems: Section 24.8. Context Connection: The Special Properties of Laser Light
Problems: Additional Problems
Chapter 25. Reflection and Refraction of Light
25.1. The Nature of Light
25.2. The Ray Model in Geometric Optics
25.3. Analysis Model: Wave under Reflection
25.4. Analysis Model: Wave under Refraction
25.5. Dispersion and Prisms
25.6. Huygens’s Principle
Huygens’s Principle Applied to Reflection and Refraction
25.7. Total Internal Reflection
25.8. Context Connection: Optical Fibers
Summary
Analysis Models for Problem Solving
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 25.2 through Section 25.4
Problems: Section 25.5. Dispersion and Prisms
Problems: Section 25.6. Huygens’s Principle
Problems: Section 25.7. Total Internal Reflection
Problems: Section 25.8. Context Connection: Optical Fibers
Problems: Additional Problems
Chapter 26. Image Formation by Mirrors and Lenses
26.1. Images Formed by Flat Mirrors
26.2. Images Formed by Spherical Mirrors
Concave Mirrors
Convex Mirrors
Ray Diagrams for Mirrors
26.3. Images Formed by Refraction
Flat Refracting Surfaces
26.4. Images Formed by Thin Lenses
Ray Diagrams for Thin Lenses
Combinations of Thin Lenses
26.5. The Eye
Conditions of the Eye
26.6. Context Connection: Some Medical Applications
Summary
Problems Icon Guide
Objective Questions
Conceptual Questions
Problems: Section 26.1. Images Formed by Flat Mirrors
Problems: Section 26.2. Images Formed by Spherical Mirrors
Problems: Section 26.3. Images Formed by Refraction
Problems: Section 26.4. Images Formed by Thin Lenses
Problems: Section 26.5. The Eye
Problems: Section 26.6. Context Connection: Some Medical Applications
Problems: Additional Problems
Chapter 27. Wave Optics
27.1. Conditions for Interference
27.2. Young’s Double-Slit Experiment
27.3. Analysis Model: Waves in Interference
Intensity Distribution of the Double-Slit Interference Pattern
27.4. Change of Phase Due to Reflection
27.5. Interference in Thin Films
27.6. Diffraction Patterns
27.7. Resolution of Single-Slit and Circular Apertures
27.8. The Diffraction Grating
27.9. Diffraction of X-Rays by Crystals
27.10. Context Connection: Holography
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