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• Chapter 1: About Science
  • 1.1: Scientific Measurements
  • 1.2: Mathematics-The Language of Science
  • 1.3: Scientific Methods
  • 1.4: The Scientific Attitude
  • 1.5: Science, Art, and Religion
  • 1.6: Science and Technology
  • 1.7: Physics-The Basic Science
  • 1.8: In Perspective
  • 1: Exercises (8)
  
  
• Chapter 2: Newton's First Law of Motion-Intertia
  • 2.1: Aristotle on Motion
  • 2.2: Copernicus and the Moving Earth
  • 2.3: Galileo and the Leaning Tower
  • 2.4: Galileo's Inclined Planes
  • 2.5: Newton's First Law of Motion
  • 2.6: Net Force
  • 2.7: The Equilibrium Rule
  • 2.8: Support Force
  • 2.9: Equilibrium of Moving Things
  • 2.10: The Moving Earth
  • 2: Exercises (36)
  
  
• Chapter 3: Linear Motion
  • 3.1: Motion is Relative
  • 3.2: Speed
  • 3.3: Velocity
  • 3.4: Acceleration
  • 3.5: Free Fall
  • 3: One-Step Calculations
  • 3: Exercises (39)
  • 3: Problems (10)
  
  
• Chapter 4: Newton's Second Law of Motion
  • 4.1: Force Causes Acceleration
  • 4.2: Friction
  • 4.3: Mass and Weight
  • 4.4: Mass Resists Acceleration
  • 4.5: Newton's Second Law of Motion
  • 4.6: When Acceleration is g -- Free Fall
  • 4.7: When Acceleration is Less than g -- Nonfree Fall
  • 4: Exercises (45)
  • 4: Problems (10)
  
  
• Chapter 5: Newton's Third Law of Motion
  • 5.1: Forces and Interactions
  • 5.2: Newton's Third Law of Motion
  • 5.3: Summary of Newton's Three Laws
  • 5.4: Vectors
  • 5: Exercises (34)
  • 5: Problems (6)
  
  
• Chapter 6: Momentum
  • 6.1: Momentum
  • 6.2: Impulse
  • 6.3: Impulse Changes Momentum
  • 6.4: Bouncing
  • 6.5: Conservation of Momentum
  • 6.6: Collisions
  • 6.7: More Complicated Collisions
  • 6: Exercises (45)
  • 6: Problems (10)
  
  
• Chapter 7: Energy
  • 7.1: Work
  • 7.2: Power
  • 7.3: Mechanical Energy
  • 7.4: Conservation of Energy
  • 7.5: Machines
  • 7.6: Efficiency
  • 7.7: Comparison of Kinetic Energy and Momentum
  • 7.8: Energy for Life
  • 7.9: Sources of Energy
  • 7: Exercises (37)
  • 7: Problems (8)
  
  
• Chapter 8: Rotational Motion
  • 8.1: Circular Motion
  • 8.2: Rotational Inertia
  • 8.3: Torque
  • 8.4: Center of Mass and Center of Gravity
  • 8.5: Centripetal Force
  • 8.6: Centrifugal Force
  • 8.7: Centrifugal Force in a Rotating Reference Frame
  • 8.8: Simulated Gravity
  • 8.9: Angular Momentum
  • 8.10: Conservation of Angular Momentum
  • 8: Exercises (38)
  • 8: Problems (10)
  
  
• Chapter 9: Gravity
  • 9.1: The Universal Law of Gravity
  • 9.2: The Universal Gravitational Constant
  • 9.3: Gravity and Distance: The Inverse-Square Law
  • 9.4: Weight and Weightlessness
  • 9.5: Ocean Tides
  • 9.6: Gravitational Fields
  • 9.7: Einstein's Theory of Gravitation
  • 9.8: Black Holes
  • 9.9: Universal Gravitation
  • 9: Exercises (49)
  • 9: Problems (6)
  
  
• Chapter 10: Projectile and Satellite Motion
  • 10.1: Projectile Motion
  • 10.2: Fast-Moving Projectiles - Satellites
  • 10.3: Circular Satellite Orbits
  • 10.4: Elliptical Orbits
  • 10.5: Kepler's Law of Planetary Motion
  • 10.6: Energy Conservation and Satellite Motion
  • 10.7: Escape Speed
  • 10: Exercises (46)
  • 10: Problems (10)
  
  
• Chapter 11: The Atomic Nature of Matter
  • 11.1: The Atomic Hypothesis
  • 11.2: Characteristics of Atoms
  • 11.3: Atomic Imagery
  • 11.4: Atomic Structure
  • 11.5: The Elements
  • 11.6: The Periodic Table of Elements
  • 11.7: Isotopes
  • 11.8: Compounds and Mixtures
  • 11.9: Molecules
  • 11.10: Antimatter
  • 11.11: Dark Matter
  • 11: Exercises (33)
  • 11: Problems (8)
  
  
• Chapter 12: Solids
  • 12.1: Muller's Micrograph
  • 12.2: Crystal Structure
  • 12.3: Density
  • 12.4: Elasticity
  • 12.5: Tension and Compression
  • 12.6: Arches
  • 12.7: Scaling
  • 12: Exercises (38)
  • 12: Problems (10)
  
  
• Chapter 13: Liquids
  • 13.1: Pressure
  • 13.2: Pressure in a Liquid
  • 13.3: Buoyancy
  • 13.4: Archimedes' Principle
  • 13.5: What Makes an Object Sink or Float?
  • 13.6: Flotation
  • 13.7: Pascal's Principle
  • 13.8: Surface Tension
  • 13.9: Capillarity
  • 13: Exercises (47)
  • 13: Problems (9)
  
  
• Chapter 14: Gases and Plasmas
  • 14.1: The Atmosphere
  • 14.2: Atmospheric Pressure
  • 14.3: Boyle's Law
  • 14.4: Buoyancy of Air
  • 14.5: Bernoulli's Principle
  • 14.6: Plasma
  • 14: Exercises (43)
  • 14: Problems (8)
  
  
• Chapter 15: Temperature, Heat, and Expansion
  • 15.1: Temperature
  • 15.2: Heat
  • 15.3: Specific Heat Capacity
  • 15.4: Thermal Expansion
  • 15: Exercises (42)
  • 15: Problems (10)
  
  
• Chapter 16: Heat Transfer
  • 16.1: Conduction
  • 16.2: Convection
  • 16.3: Radiation
  • 16.4: Newton's Law of Cooling
  • 16.5: The Greenhouse Effect
  • 16.6: Solar Power
  • 16.7: Controlling Heat Transfer
  • 16: Exercises (41)
  • 16: Problems (6)
  
  
• Chapter 17: Change of Phase
  • 17.1: Evaporation
  • 17.2: Condensation
  • 17.3: Boiling
  • 17.4: Melting and Freezing
  • 17.5: Energy and Changes of Phase
  • 17: Exercises (44)
  • 17: Problems (8)
  
  
• Chapter 18: Thermodynamics
  • 18.1: Absolute Zero
  • 18.2: Internal Energy
  • 18.3: First Law of Thermodynamics
  • 18.4: Adiabatic Processes
  • 18.5: Meteroligy and the First Law
  • 18.6: Second Law of Thermodynamics
  • 18.7: Order Tends to Disorder
  • 18.8: Entropy
  • 18: Exercises (38)
  • 18: Problems (8)
  
  
• Chapter 19: Vibrations and Waves
  • 19.1: Vibration of a Pendulum
  • 19.2: Wave Description
  • 19.3: Wave Motion
  • 19.4: Wave Speed
  • 19.5: Transverse Waves
  • 19.6: Longitudinal Waves
  • 19.7: Interference
  • 19.8: Standing Waves
  • 19.9: Doppler Effect
  • 19.10: Bow Waves
  • 19.11: Shock Waves
  • 19: Exercises (37)
  • 19: Problems (10)
  
  
• Chapter 20: Sound
  • 20.1: Speed of Sound in Air
  • 20.2: Reflection of Sound
  • 20.3: Refraction of Sound
  • 20.4: Energy in Sound Waves
  • 20.5: Forced Vibrations
  • 20.6: Natural Frequency
  • 20.7: Resonance
  • 20.8: Interference
  • 20.9: Beats
  • 20: Exercises (39)
  • 20: Problems (10)
  
  
• Chapter 21: Musical Sounds
  • 21.1: Pitch
  • 21.2: Sound Intensity and Loudness
  • 21.3: Quality
  • 21.4: Musical Instruments
  • 21.5: Fourier Analysis
  • 21.6: Compact Discs
  • 21: Exercises (37)
  • 21: Problems (5)
  
  
• Chapter 22: Electrostatics
  • 22.1: Electrical Forces
  • 22.2: Electric Charges
  • 22.3: Conservation of Charge
  • 22.4: Coulomb's Law
  • 22.5: Conductors and Insulators
  • 22.6: Superconductors
  • 22.7: Charging
  • 22.8: Charge Polarization
  • 22.9: Electric Field
  • 22.10: Electric Potential
  • 22.11: Electric Energy Storage
  • 22: Exercises (42)
  • 22: Problems (10)
  
  
• Chapter 23: Electric Current
  • 23.1: Flow of Charge
  • 23.2: Electric Current
  • 23.3: Voltage Sources
  • 23.4: Electrical Resistance
  • 23.5: Ohm's Law
  • 23.6: Direct Current and Alternating Current
  • 23.7: Speed and Source of Electrons in a Circuit
  • 23.8: Electric Power
  • 23.9: Electric Circuits
  • 23: Exercises (43)
  • 23: Problems (10)
  
  
• Chapter 24: Magnetism
  • 24.1: Magnetic Forces
  • 24.2: Magnetic Poles
  • 24.3: Magnetic Fields
  • 24.4: Magnetic Domains
  • 24.5: Electric Currents and Magnetic Fields
  • 24.6: Magnetic Force on Moving Charged Particles
  • 24.7: Magnetic Force on Current-Carrying Wires
  • 24.8: Earth's Magnetic Field
  • 24.9: Biomagnetism
  • 24: Exercises (31)
  
  
• Chapter 25: Electromagnetic Induction
  • 25.1: Electromagnetic Induction
  • 25.2: Faraday's Law
  • 25.3: Generators and Alternating Current
  • 25.4: Power Production
  • 25.5: Self-Induction
  • 25.6: Power Transmission
  • 25.7: Field Induction
  • 25.8: In Perspective
  • 25: Exercises (36)
  • 25: Problems (5)
  
  
• Chapter 26: Properties of Light
  • 26.1: Electromagnetic Waves
  • 26.2: Transparent Materials
  • 26.3: Opaque Materials
  • 26.4: Seeing Light - The Eye
  • 26: Exercises (35)
  • 26: Problems (10)
  
  
• Chapter 27: Color
  • 27.1: Selective Reflection
  • 27.2: Selective Transmission
  • 27.3: Mixing Colored Light
  • 27.4: Mixing Colored Pigments
  • 27.5: Why the Sky is Blue
  • 27.6: Why Sunsets Are Red
  • 27.7: Why Clouds are White
  • 27.8: Why Water is Greenish Blue
  • 27: Exercises (38)
  
  
• Chapter 28: Reflection and Refraction
  • 28.1: Reflection
  • 28.2: Principle of Least Time
  • 28.3: Law of Reflection
  • 28.4: Refraction
  • 28.5: Cause of Refraction
  • 28.6: Total Internal Reflection
  • 28.7: Lenses
  • 28.8: Lens Defects
  • 28: Exercises (43)
  • 28: Problems (8)
  
  
• Chapter 29: Light Waves
  • 29.1: Huygens' Principle
  • 29.2: Diffraction
  • 29.3: Interference
  • 29.4: Polarization
  • 29.5: Holography
  • 29: Exercises (37)
  
  
• Chapter 30: Light Emission
  • 30.1: Excitation
  • 30.2: Incandescence
  • 30.3: Fluorescence
  • 30.4: Phosphorescence
  • 30.5: Lasers
  • 30: Exercises (45)
  • 30: Problems (1)
  
  
• Chapter 31: Light Quanta
  • 31.1: Birth of Quantum Theory
  • 31.2: Quantization and Planck's Constant
  • 31.3: Photoelectric Effect
  • 31.4: Wave-Particle Duality
  • 31.5: Double-Slit Experiment
  • 31.6: Particles as Waves: Electron Diffraction
  • 31.7: Uncertainty Principle
  • 31.8: Complementarity
  • 31: Exercises (35)
  • 31: Problems (3)
  
  
• Chapter 32: The Atom and the Quantum
  • 32.1: The Discovery of the Atomic Nucleus
  • 32.2: Discovery of the Electron
  • 32.3: Atomic Spectra: Clues to Atomic Structure
  • 32.4: Bohr Model of the Atom
  • 32.5: Relative Sizes of Atoms
  • 32.6: Explanation of Quantized Energy Levels: Electron Waves
  • 32.7: Quantum Mechanics
  • 32.8: Correspondence Principle
  • 32: Exercises (30)
  • 32: Problems (2)
  
  
• Chapter 33: The Atomic Nucleus and Radioactivity
  • 33.1: X-Rays and Radioactivity
  • 33.2: Alpha, Beta, and Gamma Rays
  • 33.3: The Nucleus
  • 33.4: Isotopes
  • 33.5: Why Atoms are Radioactive
  • 33.6: Half-Life
  • 33.7: Transmutation of Elements
  • 33.8: Radioactive Isotopes
  • 33.9: Radiometric Dating
  • 33.10: Effects of Radiation on Humans
  • 33: Exercises (39)
  • 33: Problems (5)
  
  
• Chapter 34: Nuclear Fission and Fusion
  • 34.1: Nuclear Fission
  • 34.2: Nuclear Fission Reactors
  • 34.3: Plutonium
  • 34.4: The Breeder Reactor
  • 34.5: Fission Power
  • 34.6: Mass-Energy Equivalence
  • 34.7: Nuclear Fusion
  • 34.8: Controlling Fusion
  • 34: Exercises (38)
  • 34: Problems (3)
  
  
• Chapter 35: Special Theory of Relativity
  • 35.1: Motion is Relative
  • 35.2: Michelson-Morley Experiment
  • 35.3: Postulates of the Special Theory of Relativity
  • 35.4: Simultaneity
  • 35.5: Spacetime
  • 35.6: Time Dilation
  • 35.7: The Twin Trip
  • 35.8: Addition of Velocities
  • 35.9: Space Travel
  • 35.10: Length Contraction
  • 35.11: Relativistic Momentum
  • 35.12: Mass, Energy, and E = mc^2
  • 35.13: The Correspondance Principle
  • 35: Exercises (39)
  • 35: Problems (10)
  
  
• Chapter 36: General Theory of Relativity
  • 36.1: Principle of Equivalence
  • 36.2: Bending of Light by Gravity
  • 36.3: Gravity and Time: Gravitational Red Shift
  • 36.4: Gravity and Space: Motion of Mercury
  • 36.5: Gravity, Space, and a New Geometry
  • 36.6: Gravitational Waves
  • 36.7: Newtonian and Einsteinian Gravitation
  • 36: Exercises (30)