Principles of Physics 5th edition

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• Chapter 1: Introduction and Vectors
  • 1.1: Standards of 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
  • 1.9: Components of a Vector and Unit Vectors
  • 1.10: Modeling, Alternative Representations, and Problem-Solving Strategy
  • 1: Additional Problems
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• 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
  • 2: Additional Problems
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• 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
  • 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
  • 3: Additional Problems
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• 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
  • 4.5: The Gravitational Force and Weight
  • 4.6: Newton's Third Law
  • 4.7: Analysis Models Using Newton's Second Law
  • 4.8: Context Connection: Forces on Automobiles
  • 4: Additional Problems
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• 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
  • 5.5: The Fundamental Forces of Nature
  • 5.6: Context Connection: Drag Coefficients of Automobiles
  • 5: Additional Problems
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• 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
  • 6.5: Kinetic Energy and the Work-Kinetic Energy Theorem
  • 6.6: Potential Energy of a System
  • 6.7: Conservative and 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
  • 6: Additional Problems
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• 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
  • 7: Additional Problems
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• 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
  • 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
  • 8: Additional Problems
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• 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
  • 9.5: The Lorentz Transformation Equations
  • 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
  • 9: Additional Problems
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• 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
  • 10: Additional Problems
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• Chapter 11: Gravity, Planetary Orbits, and the Hydrogen Atom
  • 11.1: Newton's Law of Universal Gravitation Revisited
  • 11.2: Structural Models
  • 11.3: Kepler's Laws
  • 11.4: Energy Considerations in Planetary and Satellite Motion
  • 11.5: Atomic Spectra and the Bohr Theory of Hydrogen
  • 11.6: Context Connection: Changing from a Circular to an Elliptical Orbit
  • 11: Additional Problems
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• 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 Connections: Resonance in Structures
  • 12: Additional Problems
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• Chapter 13: Mechanical Waves
  • 13.1: Propagation of a Disturbance
  • 13.2: Analysis Model: Traveling Wave
  • 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
  • 13.8: Context Connection: Seismic Waves
  • 13: Additional Problems
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• Chapter 14: Superposition and Standing Waves
  • 14.1: Analysis Model: Waves in Interference
  • 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
  • 14.8: Context Connection: Building on Antinodes
  • 14: Additional Problems
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• 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
  • 15.5: Fluid Dynamics
  • 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
  • 15: Additional Problems
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• Chapter 16: Temperature and the Kinetic Theory of Gases
  • 16.1: Temperature and the Zeroth Law of Thermodynamics
  • 16.2: Thermometers and Temperature Scales
  • 16.3: Thermal Expansion of Solids and Liquids
  • 16.4: Macroscopic Description of an Ideal Gas
  • 16.5: The Kinetic Theory of Gases
  • 16.6: Distribution of Molecular Speeds
  • 16.7: Context Connection: The Atmospheric Lapse Rate
  • 16: Additional Problems
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• Chapter 17: Energy in Thermal Processes: The First Law of Thermodynamics
  • 17.1: Heat and Internal Energy
  • 17.2: Specific Heat
  • 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
  • 17.10: Energy Transfer Mechanisms in Thermal Processes
  • 17.11: Context Connection: Energy Balance for the Earth
  • 17: Additional Problems
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• 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
  • 18.9: Context Connection: The Atmosphere as a Heat Engine
  • 18: Additional Problems
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• Chapter 19: Electric Forces and Electric Fields
  • 19.1: Historical Overview
  • 19.2: Properties of Electric Charges
  • 19.3: Insulators and Conductors
  • 19.4: Coulomb's Law
  • 19.5: Electric Fields
  • 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
  • 19: Additional Problems
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• 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
  • 20.7: Capacitance
  • 20.8: Combinations of Capacitors
  • 20.9: Energy Stored in a Charged Capacitor
  • 20.10: Capacitors with Dielectrics
  • 20.11: Context Connection: The Atmosphere as a Capacitor
  • 20: Additional Problems
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• Chapter 21: Current and Direct Current Circuits
  • 21.1: Electric Current
  • 21.2: Resistance and Ohm's Law
  • 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
  • 21.10: Context Connection: The Atmosphere as a Conductor
  • 21: Additional Problems
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• 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
  • 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
  • 22.12: Context Connection: Remote Magnetic Navigation for Cardiac Catheter Ablation Procedures
  • 22: Additional Problems
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• Chapter 23: Faraday's Law and Inductance
  • 23.1: Faraday's Law of Induction
  • 23.2: Motional emf
  • 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
  • 23: Additional Problems
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• 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
  • 24.4: Energy Carried by Electromagnetic Waves
  • 24.5: Momentum and Radiation Pressure
  • 24.6: The Spectrum of Electromagnetic Waves
  • 24.7: Polarization of Light Waves
  • 24.8: Context Connection: The Special Properties of Laser Light
  • 24: Additional Problems
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• 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: Huygen's Principle
  • 25.7: Total Internal Reflection
  • 25.8: Context Connection: Optical Fibers
  • 25: Additional Problems
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• Chapter 26: Image Formation by Mirrors and Lenses
  • 26.1: Images Formed by Flat Mirrors
  • 26.2: Images Formed by Spherical Mirrors
  • 26.3: Images Formed by Refraction
  • 26.4: Images Formed by Thin Lenses
  • 26.5: The Eye
  • 26.6: Context Connection: Some Medical Applications
  • 26: Additional Problems
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• Chapter 27: Wave Optics
  • 27.1: Conditions for Interference
  • 27.2: Young's Double-Slit Experiment
  • 27.3: Analysis Model: Waves in Interference
  • 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
  • 27: Additional Problems
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• Chapter 28: Quantum Physics
  • 28.1: Blackbody Radiation and Planck's Theory
  • 28.2: The Photoelectric Effect
  • 28.3: The Compton Effect
  • 28.4: Photons and Electromagnetic Waves
  • 28.5: The Wave Properties of Particles
  • 28.6: A New Model: The Quantum Particle
  • 28.7: The Double-Slit Experiment Revisited
  • 28.8: The Uncertainty Principle
  • 28.9: An Interpretation of Quantum Mechanics
  • 28.10: A Particle in a Box
  • 28.11: Analysis Model: Quantum Particle Under Boundary Conditions
  • 28.12: The Schrödinger Equation
  • 28.13: Tunneling Through a Potential Energy Barrier
  • 28.14: Context Connection: The Cosmic Temperature
  • 28: Additional Problems
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• Chapter 29: Atomic Physics
  • 29.1: Early Structural Models of the Atom
  • 29.2: The Hydrogen Atom Revisited
  • 29.3: The Wave Functions for Hydrogen
  • 29.4: Physical Interpretation of the Quantum Numbers
  • 29.5: The Exclusion Principle and the Periodic Table
  • 29.6: More on Atomic Spectra: Visible and X-Ray
  • 29.7: Context Connection: Atoms in Space
  • 29: Additional Problems
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• Chapter 30: Nuclear Physics
  • 30.1: Some Properties of Nuclei
  • 30.2: Nuclear Binding Energy
  • 30.3: Radioactivity
  • 30.4: The Radioactive Decay Processes
  • 30.5: Nuclear Reactions
  • 30.6: Context Connection: The Engine of the Stars
  • 30: Additional Problems
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• Chapter 31: Particle Physics
  • 31.1: The Fundamental Forces in Nature
  • 31.2: Positrons and Other Antiparticles
  • 31.3: Mesons and the Beginning of Particle Physics
  • 31.4: Classification of Particles
  • 31.5: Conservation Laws
  • 31.6: Strange Particles and Strangeness
  • 31.7: Measuring Particle Lifetimes
  • 31.8: Finding Patterns in the Particles
  • 31.9: Quarks
  • 31.10: Multicolored Quarks
  • 31.11: The Standard Model
  • 31.12: Context Connection: Investigating the Smallest System to Understand the Largest
  • 31: Additional Problems
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• Chapter Q1: Quick Prep: Keeping It in the Ballpark
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• Chapter Q2: Quick Prep: The Motion of Objects Along a Line
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• Chapter Q3: Quick Prep: Those Special Functions
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• Chapter Q4: Quick Prep: Elements of Approximation and Graphing
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• Chapter Q5: Quick Prep: Probability and Error
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• Chapter Q6: Quick Prep: Return to Lineland
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• Chapter Q7: Quick Prep: Vectors, Displacement, and Velocity
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• Chapter Q8: Quick Prep: Life on a Sphere
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• Chapter Q9: Quick Prep: Force
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• Chapter Q10: Quick Prep: Vector Projections
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