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• Chapter 1: Introduction, Measurement, Estimating
  • 1.1: The Nature of Science
  • 1.2: Models, Theories, and Laws
  • 1.3: Measurement and Uncertainty; Significant Figures (5)
  • 1.4: Units, Standards, and the SI System (3)
  • 1.5: Converting Units (2)
  • 1.6: Order of Magnitude: Rapid Estimating (3)
  • 1.7: Dimensions and Dimensional Analysis
  • 1: General Problems (8)
  
  
• Chapter 2: Describing Motion: Kinematics in One Dimension
  • 2.1: Reference Frames and Displacement (3)
  • 2.2: Average Velocity (2)
  • 2.3: Instantaneous Velocity (4)
  • 2.4: Acceleration (4)
  • 2.5: Motion at Constant Acceleration (5)
  • 2.6: Solving Patterns (3)
  • 2.7: Falling Objects (9)
  • 2.8: Use of Calculus; Variable Acceleration (1)
  • 2: General Problems (11)
  
  
• Chapter 3: Kinematics in Two Dimensions; Vectors
  • 3.1: Vectors and Scalars (2)
  • 3.2: Addition of Vectors-Graphical Methods (1)
  • 3.3: Subtraction of Vectors, and Multiplication of a Vector by a Scalar (2)
  • 3.4: Adding Vectors by Components (3)
  • 3.5: Unit Vectors (3)
  • 3.6: Vector Kinematics (3)
  • 3.7: Projectile Motion (7)
  • 3.8: Solving Problems in Projectile Motion (1)
  • 3.9: Uniform Circular Motion (4)
  • 3.10: Relative Velocity (3)
  • 3: General Problems (12)
  • 3: Questions (10)
  
  
• Chapter 4: Dynamics: Newton's Laws of Motion
  • 4.1: Force
  • 4.2: Newton's First Law of Motion
  • 4.3: Mass
  • 4.4: Newton's Second Law of Motion (7)
  • 4.5: Newton's Third Law of Motion (3)
  • 4.6: Weight-The Force of Gravity; and the Normal Force (5)
  • 4.7: Solving Problems with Newton's Laws: Free-Body Diagrams (13)
  • 4.8: Problem Solving-A General Approach
  • 4: General Problems (12)
  
  
• Chapter 5: Further Applications of Newton's Laws
  • 5.1: Applications of Newton's Laws Involving Friction (15)
  • 5.2: Dynamics of Uniform Circular Motion (4)
  • 5.3: Highway Curves, Banked and Unbanked (5)
  • 5.4: Nonuniform Circular Motion (2)
  • 5.5: Velocity-Dependent Forces; Terminal Velocity (2)
  • 5: General Problems (17)
  
  
• Chapter 6: Gravitation and Newton's Synthesis
  • 6.1: Newton's Law of Universal Gravitation (4)
  • 6.2: Vector Form of Newton's Law of Universal Gravitation (1)
  • 6.3: Gravity Near the Earth's Surface; Geophysical Applications (2)
  • 6.4: Satellites and "Weightlessness" (7)
  • 6.5: Kepler's Laws and Newton's Synthesis (4)
  • 6.6: Gravitational Field
  • 6.7: Types of Forces in Nature
  • 6.8: Gravitational Versus Inertial Mass; the Principal of Equivalence
  • 6.9: Gravitation as Curvature of Space; Black Holes
  • 6: General Problems (9)
  
  
• Chapter 7: Work and Energy
  • 7.1: Work Done by a Constant Force (7)
  • 7.2: Scalar Product of Two Vectors (5)
  • 7.3: Work Done by a Varying Force (5)
  • 7.4: Kinetic Energy and the Work-Energy Principle (11)
  • 7.5: Kinetic Energy at Very High Speed
  • 7: General Problems (8)
  
  
• Chapter 8: Conservation of Energy
  • 8.1: Conservative and Nonconservative Forces (4)
  • 8.2: Potential Energy (1)
  • 8.3: Mechanical Energy and Its Conservation (5)
  • 8.4: Problem Solving Using Conservation of Mechanical Energy (4)
  • 8.5: The Law of Conservation of Energy (3)
  • 8.6: Energy Conservation with Dissipative Forces: Solving Problems (4)
  • 8.7: Gravitational Potential Energy and Escape Velocity (7)
  • 8.8: Power (6)
  • 8.9: Potential Energy Diagrams; Stable and Unstable Equilibrium (1)
  • 8: General Problems (3)
  
  
• Chapter 9: Linear Momentum and Collisions
  • 9.1: Momentum and Its Relation to Force (5)
  • 9.2: Conservation of Momentum (6)
  • 9.3: Collisions and Impulse (4)
  • 9.4: Conservation of Energy and Momentum in Collisions (6)
  • 9.5: Elastic Collisions in One Dimension (1)
  • 9.6: Inelastic Collisions (4)
  • 9.7: Collisions in Two or Three Dimensions (4)
  • 9.8: Center of Mass (CM) (12)
  • 9.9: Center of Mass and Translational Motion
  • 9.10: Systems of Variable Mass; Rocket Propulsion (4)
  • 9: General Problems (7)
  
  
• Chapter 10: Rotational Motion About a Fixed Axis
  • 10.1: Angular Quantities (3)
  • 10.2: Kinematic Equations for Uniformly Accelerated Rotational Motion (5)
  • 10.3: Rolling Motion (without Slipping) (4)
  • 10.4: Vector Nature of Angular Quantities (1)
  • 10.5: Torque (5)
  • 10.6: Rotational Dynamics; Torque and Rotational Intertia (2)
  • 10.7: Solving Problems in Rotational Dynamics (4)
  • 10.8: Determining Moments of Intertia (3)
  • 10.9: Angular Momentum and Its Conservation (6)
  • 10.10: Rotational Kinetic Energy (4)
  • 10.11: Rotational Plus Traditional Motion; Rolling (5)
  • 10.12: Why Does a Rolling Sphere Slow Down?
  • 10: General Problems (14)
  
  
• Chapter 11: General Rotation
  • 11.1: Vector Cross Product (1)
  • 11.2: The Torque Vector (3)
  • 11.3: Angular Momentum of a Particle (3)
  • 11.4: Angular Momentum and Torque for a System of Particles; General Motion (4)
  • 11.5: Angular Momentum and Torque for a Rigid Body (2)
  • 11.6: Rotational Imbalance
  • 11.7: Conservation of Angular Momentum (4)
  • 11.8: The Spinning Top (2)
  • 11.9: Rotating Frames of Reference; Inertial Forces (1)
  • 11.10: The Coriolis Effect (3)
  • 11: General Problems (6)
  
  
• Chapter 12: Static Equilibrium; Elasticity and Fracture
  • 12.1: Statics-The Study of Forces in Equilibrium (9)
  • 12.2: The Conditions for Equilibrium (12)
  • 12.3: Solving Statics Problems (9)
  • 12.4: Stability and Balance
  • 12.5: Elasticity; Stress and Strain (7)
  • 12.6: Fracture (4)
  • 12.7: Trusses and Bridges (2)
  • 12.8: Arches and Domes (2)
  • 12: General Problems (10)
  
  
• Chapter 13: Fluids
  • 13.1: Density and Specific Gravity (2)
  • 13.2: Pressure in Fluids (2)
  • 13.3: Atmospheric Pressure and Gauge Pressure (4)
  • 13.4: Pascal's Principle (2)
  • 13.5: Measurement of Pressure; Gauges and the Barometer (2)
  • 13.6: Buoyancy and Archimedes' Principle (7)
  • 13.7: Fluids in Motion; Flow Rate and the Equation of Continuity (3)
  • 13.8: Bernoulli's Equation (4)
  • 13.9: Applications of Bernoulli's Principle: From Torricelli to Sailboats, Airfoils, and TIA (2)
  • 13.10: Viscosity
  • 13.11: Flow in Tubes: Poiseuille's Equation (4)
  • 13.12: Surface Tension and Capillarity (2)
  • 13.13: Pumps
  • 13: General Problems (7)
  
  
• Chapter 14: Oscillations
  • 14.1: Oscillations of a Spring (9)
  • 14.2: Simple Harmonic Motion (6)
  • 14.3: Energy in the Simple Harmonic Oscillator (7)
  • 14.4: Simple Harmonic Motion Related to Uniform Circular Motion
  • 14.5: The Simple Pendulum (4)
  • 14.6: Physical Pendulum and Torsion Pendulum (1)
  • 14.7: Damped Harmonic Motion (3)
  • 14.8: Forced Vibrations; Resonance (1)
  • 14: General Problems (12)
  
  
• Chapter 15: Wave Motion
  • 15.1: Characteristics of Wave Motion (6)
  • 15.2: Wave Types (3)
  • 15.3: Energy Transported by Waves (4)
  • 15.4: Mathematical Representation of a Traveling Wave (3)
  • 15.5: The Wave Equation (2)
  • 15.6: The Principle of Superposition
  • 15.7: Reflection and Transmission (1)
  • 15.8: Interference
  • 15.9: Standing Waves; Resonance (8)
  • 15.10: Refraction (4)
  • 15.11: Diffraction
  • 15: General Problems (9)
  
  
• Chapter 16: Sound
  • 16.1: Characteristics of Sound (4)
  • 16.2: Mathematical Representation of Longitudunal Waves (3)
  • 16.3: Intensity of Sound; Decibles (10)
  • 16.4: Sources of Sound: Vibrating Strings and Air Columns (9)
  • 16.5: Quality of Sound, and Noise
  • 16.6: Interference of Sound Waves; Beats (7)
  • 16.7: Doppler Effect (5)
  • 16.8: Shock Waves and the Sonic Boom (1)
  • 16.9: Applications; Ultrasound and Ultrasound Imaging
  • 16: General Problems (5)
  
  
• Chapter 17: Temperature, Thermal Expansion, and the Ideal Gas Law
  • 17.1: Atomic Theory of Matter (1)
  • 17.2: Temperature and Thermodynamics (2)
  • 17.3: Thermal Equilibrium and the Zeroth Law of Thermodynamics
  • 17.4: Thermal Expansion (4)
  • 17.5: Thermal Stresses (1)
  • 17.6: The Gas Laws and Absolute Temperature (1)
  • 17.7: The Ideal Gas Law (2)
  • 17.8: Problem Solving with the Ideal Gas Law (3)
  • 17.9: Ideal Gas Law in Terms of Molecules: Avogadro's Number (3)
  • 17.10: Ideal Gas Temperature Scale-A Standard
  • 17: General Problems (6)
  
  
• Chapter 18: Kinetic Theory of Gases
  • 18.1: The Ideal Gas Law and the Molecular Interpretation of Temperatures (5)
  • 18.2: Distribution of Molecular Speeds (1)
  • 18.3: Real Gases and Changes of Phase (1)
  • 18.4: Vapor Pressure and Humidity (3)
  • 18.5: Van der Waals Equation of State
  • 18.6: Mean Free Path
  • 18.7: Diffusion (2)
  • 18: General Problems (6)
  
  
• Chapter 19: Heat and the First Law of Thermodynamics
  • 19.1: Heat as Energy Transfer (5)
  • 19.2: Internal Energy
  • 19.3: Specific Heat (5)
  • 19.4: Calorimetry-Solving Problems (3)
  • 19.5: Latent Heat (10)
  • 19.6: The First Law of Thermodynamics (6)
  • 19.7: Applying the First Law of Thermodynamics; Calculating the Work (3)
  • 19.8: Molar Specific Heats for Gases, and the Equipartition of Energy (4)
  • 19.9: Adiabatic Expansion of a Gas (4)
  • 19.10: Heat Transfer: Conduction, Convection, Radiation (9)
  • 19: General Problems (10)
  
  
• Chapter 20: Second Law of Thermodynamics; Heat Engines
  • 20.1: The Second Law of Thermodynamics-Introduction
  • 20.2: Heat Engines (4)
  • 20.3: Reversible and Irreversible Processes; The Carnot Engine (8)
  • 20.4: Refrigerators, Air Conditioners, and Heat Pumps (9)
  • 20.5: Entropy (6)
  • 20.6: Entropy and the Second Law of Thermodynamics (5)
  • 20.7: Order to Disorder
  • 20.8: Energy Availability; Heat Death
  • 20.9: Statistical Interpretation of Entropy and the Second Law
  • 20.10: Thermodynamic Temperature Scale; Absolute Zero and the Third Law of Thermodynamics
  • 20: General Problems (8)
  
  
• Chapter 21: Electric Charge and Electric Field
  • 21.1: Static Electricity; Electric Charge and Its Conservation
  • 21.2: Electric Charge in the Atom
  • 21.3: Insulators and Conductors
  • 21.4: Induced Charge; the Electroscope
  • 21.5: Coulomb's Law (14)
  • 21.6: The Electric Field (5)
  • 21.7: Electric Field Calculations for Continuous Charge Distributions (7)
  • 21.8: Field Lines (4)
  • 21.9: Electric Fields and Conductors
  • 21.10: Motion of a Charged Particle in an Electric Field (4)
  • 21.11: Electric Dipoles (2)
  • 21: General Problems (14)
  
  
• Chapter 22: Gauss's Law
  • 22.1: Electric Flux (2)
  • 22.2: Gauss's Law (2)
  • 22.3: Applications of Gauss's Law (9)
  • 22.4: Experimental Basis of Gauss's and Coulomb's Law
  • 22: General Problems (9)
  
  
• Chapter 23: Electric Potential
  • 23.1: Electric Potential and Potential Difference (4)
  • 23.2: Relation Between Electric Potential and Electric Field (5)
  • 23.3: Electric Potential due to Point Charges (6)
  • 23.4: Potential Due to Any Charge Distribution (1)
  • 23.5: Equipotential Surfaces (2)
  • 23.6: Electric Dipoles (3)
  • 23.7: E Determined from V (3)
  • 23.8: Electrostatic Potential Energy; the Electron Volt (4)
  • 23.9: Cathode Ray Tube: TV and Computer Monitors, Oscilloscope (1)
  • 23: General Problems (8)
  
  
• Chapter 24: Capacitance, Dielectrics, Electric Energy Storage
  • 24.1: Capacitors (7)
  • 24.2: Determination of Capacitance (6)
  • 24.3: Capacitors in Series and Parallel (7)
  • 24.4: Electric Energy Storage (6)
  • 24.5: Dielectrics (2)
  • 24.6: Molecular Description of Dielectrics
  • 24: General Problems (12)
  
  
• Chapter 25: Electric Currents and Resistance
  • 25.1: The Electric Battery
  • 25.2: Electric Current (2)
  • 25.3: Ohm's Law: Resistance and Resistors (5)
  • 25.4: Resistivity (8)
  • 25.5: Electric Power (4)
  • 25.6: Power in Household Circuits (6)
  • 25.7: Alternating Current (4)
  • 25.8: Microscopic View of Electric Current: Current Density and Drift Velocity (3)
  • 25.9: Superconductivity
  • 25.10: Electric Hazards; Leakage Currents
  • 25: General Problems (16)
  
  
• Chapter 26: DC Circuits
  • 26.1: EMF and Terminal Voltage (3)
  • 26.2: Resistors in Series and in Parallel (10)
  • 26.3: Kirchhoff's Rules (6)
  • 26.4: Circuits Containing Resistor and Capacitor (RC Circuits) (4)
  • 26.5: DC Ammeters and Voltmeters (6)
  • 26.6: Transducers and the Thermocouple
  • 26: General Problems (13)
  
  
• Chapter 27: Magnetism
  • 27.1: Magnets and Magnetic Fields
  • 27.2: Electric Currents Produce Magnetism
  • 27.3: Force on an Electric Current in a Magnetic Field; Definition of B (5)
  • 27.4: Force on an Electric Charge Moving in a Magnetic Field (7)
  • 27.5: Torque on a Current Loop; Magnetic Dipole Moment (3)
  • 27.6: Applications: Galvanometers, Motors, Loudspeakers (2)
  • 27.7: Discovery and Properties of the Electron (2)
  • 27.8: The Hall Effect (2)
  • 27.9: Mass Spectrometer (3)
  • 27: General Problems (8)
  
  
• Chapter 28: Sources of Magnetic Field
  • 28.1: Magnetic Field Due to a Straight Wire (8)
  • 28.2: Force Between Two Parallel Waves (5)
  • 28.3: Operational Definitions of the Ampere and the Coulomb
  • 28.4: Ampere's Law (2)
  • 28.5: Magnetic Field of a Solenoid and a Toroid (2)
  • 28.6: Biot-Savart Law (2)
  • 28.7: Magnetic Materials-Ferromagnetism
  • 28.8: Electromagnets and Solenoids
  • 28.9: Magnetic Fields in Magnetic Materials; Hysteresis (2)
  • 28.10: Paramagnetism and Diamagnetism
  • 28: General Problems (7)
  
  
• Chapter 29: Electromagnetic Induction and Faraday's Law
  • 29.1: Induced EMF (8)
  • 29.2: Faraday's Law of Induction; Lenz's Law (4)
  • 29.3: EMF Induced in a Moving Conductor (3)
  • 29.4: Electric Generators (2)
  • 29.5: Counter EMF and Torque; Eddy Currents (3)
  • 29.6: Transformers and Transmission of Power (5)
  • 29.7: A Changing Magnetic Flux Produces an Electric Field
  • 29.8: Applications of Induction: Sound Systems, Computer Memory, the Seismograph
  • 29: General Problems (9)
  
  
• Chapter 30: Inductance; and Electromagnetic Oscillations
  • 30.1: Mutual Inductance (1)
  • 30.2: Self-Inductance (5)
  • 30.3: Energy Stored in a Magnetic Field (4)
  • 30.4: LR Circuits (4)
  • 30.5: LC Circuits and Electromagnetic Oscillations (3)
  • 30.6: LC Oscillations with Resistance (LRC Circuits) (3)
  • 30: General Problems (1)
  
  
• Chapter 31: AC Circuits
  • 31.1: Introduction to AC Circuits (3)
  • 31.2: AC Circuit Containing Only Resistance R (1)
  • 31.3: AC Circuit Containing Only Inductance L (2)
  • 31.4: AC Circuit Containing Only Capacitance C (2)
  • 31.5: LRC Series AC Circuit (7)
  • 31.6: Resonance in AC Circuits (4)
  • 31.7: Impedance Matching (1)
  • 31.8: Three-Phase AC
  • 31: General Problems
  
  
• Chapter 32: Maxwell's Equations and Electromagnetic Waves
  • 32.1: Changing Electric Fields Produce Magnetic Fields; Ampère's Law and Displacement Current (4)
  • 32.2: Gauss's Law for Magnetism
  • 32.3: Maxwell's Equations
  • 32.4: Production of Electromagnetic Waves
  • 32.5: Electromagnetic Waves, and Their Speed, from Maxwell's Equations (3)
  • 32.6: Light as an Electromagnetic Wave and the Electromagnetic Spectrum (4)
  • 32.7: Energy in EM Waves; the Poynting Vector (4)
  • 32.8: Radiation Pressure (3)
  • 32.9: Radio and Television (3)
  • 32: General Problems (11)
  
  
• Chapter 33: Light: Reflection and Refraction
  • 33.1: The Ray Model of Light
  • 33.2: The Speed of Light and Index of Refraction (6)
  • 33.3: Reflection: Image Formation by a Plane Mirror (4)
  • 33.4: Formation of Images by Spherical Mirrors (8)
  • 33.5: Refraction: Snell's Law (4)
  • 33.6: Visible Spectrum and Dispersion (1)
  • 33.7: Total Internal Reflection; Fiber Optics (4)
  • 33.8: Refraction at a Spherical Surface
  • 33: General Problems
  
  
• Chapter 34: Lenses and Optical Instruments
  • 34.1: Thin Lenses; Ray Tracing (4)
  • 34.2: The Lens Equation (3)
  • 34.3: Combinations of Lenses (3)
  • 34.4: Lensmaker's Equation (4)
  • 34.5: Cameras (2)
  • 34.6: The Human Eye; Corrective Lenses (6)
  • 34.7: Magnifying Glass (2)
  • 34.8: Telescopes (2)
  • 34.9: Compound Microscope (3)
  • 34.10: Aberrations of Lenses and Mirrors
  • 34: General Problems (4)
  
  
• Chapter 35: Wave Nature of Light; Interference
  • 35.1: Huygens' Principle and Diffraction
  • 35.2: Huygens' Principle and the Law of Refraction
  • 35.3: Interference-Young's Double Slit Experiment (8)
  • 35.4: Coherence
  • 35.5: Intensity in the Double-Slit Interference Pattern
  • 35.6: Interference in Thin Films (6)
  • 35.7: Michelson Interferometer (2)
  • 35.8: Luminous Intensity
  • 35: General Problems (1)
  
  
• Chapter 36: Diffraction and Polarization
  • 36.1: Diffraction by a Single Slit (4)
  • 36.2: Intensity in a Single-Slit Diffraction Pattern
  • 36.3: Diffraction in a Double-Slit Experiment
  • 36.4: Limits of Resolution; Circular Apertures (1)
  • 36.5: Resolution of Telescopes and Microscopes; the λ Limit
  • 36.6: Resolution of the Human Eye and Useful Magnification
  • 36.7: Diffraction Grating (4)
  • 36.8: The Spectrometer and Spectroscopy
  • 36.9: Peak Widths and Resolving Power for a Diffraction Grating
  • 36.10: X-Rays and X-Ray Diffraction (1)
  • 36.11: Polarization (2)
  • 36.12: Scattering of Light by the Atmosphere
  • 36: General Problems (3)
  
  
• Chapter 37: Special Theory of Relativity
  • 37.1: Galilean-Newtonian Relativity
  • 37.2: The Michelson-Morely Experiment
  • 37.3: Postulates of the Special Theory of Relativity
  • 37.4: Simultaneity (2)
  • 37.5: Time Dilation and the Twin Paradox (2)
  • 37.6: Length Contraction (1)
  • 37.7: Four Dimensional Space-Time
  • 37.8: Galilean and Lorentz Transformations (4)
  • 37.9: Relativistic Momentum and Mass (1)
  • 37.10: The Ultimate Speed
  • 37.11: Energy and Mass; E = mc² (9)
  • 37.12: Doppler Shift for Light
  • 37.13: The Impact of Special Relativity
  • 37: General Problems (5)
  
  
• Chapter 38: Early Quantum Theory and Models of the Atom
  • 38.1: Planck's Quantum Hypothesis (5)
  • 38.2: Photon Theory of Light and the Photoelectric Effect (4)
  • 38.3: Photons and the Compton Effect (2)
  • 38.4: Photon Interactions; Pair Production (2)
  • 38.5: Wave-Particle Duality; the Principle of Complementarity (4)
  • 38.6: Wave Nature of Matter
  • 38.7: Electron Microscopes (2)
  • 38.8: Early Models of the Atom
  • 38.9: Atomic Spectra: Key to the Structure of the Atom (3)
  • 38.10: The Bohr Model
  • 38.11: De Broglie's Hypothesis Applied to Atoms
  • 38: General Problems (3)
  
  
• Chapter 39: Quantum Mechanics
  • 39: End of Chapter Problems (15)
  
  
• Chapter 40: Quantum Mechanics of Atoms
  • 40: End of Chapter Problems (15)
  
  
• Chapter 41: Molecules and Solids
  • 41: End of Chapter Problems (15)
  
  
• Chapter 42: Nuclear Physics and Radioactivity
  • 42: End of Chapter Problems (15)
  
  
• Chapter 43: Nuclear Energy: Effects and Uses of Radiation
  • 43: End of Chapter Problems (15)
  
  
• Chapter 44: Elementary Particles
  • 44: End of Chapter Problems (15)
  
  
• Chapter 45: Astrophysics and Cosmology
  • 45: End of Chapter Problems (15)