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• Chapter 1: Introduction
  • 1.1: Physics and the Laws of Nature
  • 1.2: Units of Length, Mass, and Time (2)
  • 1.3: Dimensional Analysis (1)
  • 1.4: Significant Figures (6)
  • 1.5: Converting Units (12)
  • 1.6: Order-of-Magnitude (2)
  • 1.7: Problem Solving in Physics (5)
  
  
• Chapter 2: Mechanics
  • 2.1: Position, Distance, and Displacement (5)
  • 2.2: Average Speed and Velocity (11)
  • 2.3: Instantaneous Velocity (1)
  • 2.4: Acceleration (8)
  • 2.5: Motion with Constant Acceleration (4)
  • 2.6: Applications of the Equations of Motion (10)
  • 2.7: Freely Falling Objects (24)
  
  
• Chapter 3: Vector in Physics
  • 3.1: Scalars Versus Vectors
  • 3.2: The Componets of a Vector (8)
  • 3.3: Adding and Subtracting Vectors (5)
  • 3.4: Unit Vectors (5)
  • 3.5: Position, Displacement, Velocity, and Acceleration Vectors (7)
  • 3.6: Relative Motion (14)
  
  
• Chapter 4: Two-Dimensional Kinematics
  • 4.1: Motion in Two Dimensions (4)
  • 4.2: Projectile Motion: Basic Equations
  • 4.3: Zero Launch Angle (9)
  • 4.4: General Launch Angle (9)
  • 4.5: Projectile Motion: Key Characteristics (24)
  
  
• Chapter 5: Newton's Laws of Motion
  • 5.1: Force and Mass
  • 5.2: Newton's First Law of Motion
  • 5.3: Newton's Second Law of Motion (7)
  • 5.4: Newton's Third Law of Motion (4)
  • 5.5: The Vector Nature of Forces: Forces in Two Dimensions (6)
  • 5.6: Weight (5)
  • 5.7: Normal Forces (18)
  
  
• Chapter 6: Applications of Newton's Law
  • 6.1: Frictional Forces (5)
  • 6.2: Strings and Springs (8)
  • 6.3: Translational Equilibrium (7)
  • 6.4: Connected Objects (4)
  • 6.5: Circular Motion (31)
  
  
• Chapter 7: Work and Kinetic Energy
  • 7.1: Work Done by a Constant Force (8)
  • 7.2: Kinetic Energy and the Work-Energy Theorum (7)
  • 7.3: Work Done by a Variable Force (8)
  • 7.4: Power (23)
  
  
• Chapter 8: Potential Energy and Conservative Forces
  • 8.1: Conservative and Nonconservative Forces (4)
  • 8.2: Potential Energy and the Work Done by Conservative Forces (4)
  • 8.3: Conservation of Mechanical Energy (8)
  • 8.4: Work Done by Nonconservative Forces (8)
  • 8.5: Potential Energy Curves and Equipotentials (24)
  
  
• Chapter 9: Linear Momentum and Collisions
  • 9.1: Linear Momentum (5)
  • 9.2: Momentum and Newton's Second Law
  • 9.3: Impulse (5)
  • 9.4: The Conservation of Linear Momentum (5)
  • 9.5: Inelastic Collisions (6)
  • 9.6 :Elastic Collisions (5)
  • 9.7: Center of Mass (5)
  • 9.8: Systems with Changing Mass: Rocket Propulsion (18)
  
  
• Chapter 10: Rotational Kinemativs and Energy
  • 10.1: Angular Position, Velocity, and Acceleration (5)
  • 10.2: Rotational Kinematics (8)
  • 10.3: Connections Between Linear and Rotational Quantities (9)
  • 10.4: Rolling Motion (4)
  • 10.5: Rotational Kinetic Energy and Moment of Inertia (6)
  • 10.6: Conservation of Energy (22)
  
  
• Chapter 11: Rotational Dynamics and Static Equilibrium
  • 11.1: Torque (4)
  • 11.2: Torque and Angular Acceleration (7)
  • 11.3: Zero Torque and Static Equilibrium (11)
  • 11.4: Center of Mass and Balance (3)
  • 11.5: Dynamic Applications of Torque (5)
  • 11.6: Angular Momentum (6)
  • 11.7: Conservation of Angular Momentum (7)
  • 11.8: Rotational Work (12)
  • 11.9: The Vector Nature of Rotational Motion
  
  
• Chapter 12: Gravity
  • 12.1: Newton's Law of Universal Gravitation (9)
  • 12.2: Gravitational Attraction of Spherical Bodies (7)
  • 12.3: Kepler's Laws of Orbital Motion (9)
  • 12.4: Gravitational Potential Energy (4)
  • 12.5: Energy Conservation (10)
  • 12.6: Tides (10)
  
  
• Chapter 13: Oscillations About Equilibrium
  • 13.1: Periodic Motion (3)
  • 13.2: Simple Harmonic Motion (3)
  • 13.3: Connections Between Uniform Circular Motion and Simple Harmonic Motion (8)
  • 13.4: The Period of a Mass on a String (7)
  • 13.5: Energy Conservation In Oscillatory Motion (7)
  • 13.6: The Pendulum (21)
  • 13.7: Damped Oscillations
  • 13.8: Driven Oscillations and Resonances
  
  
• Chapter 14: Waves and Sounds
  • 14.1: Types of Waves (4)
  • 14.2: Waves on a String (4)
  • 14.3: Harmonic Wave Functions (2)
  • 14.4: Sound Waves (3)
  • 14.5: Sound Intensity (6)
  • 14.6: The Doppler Effect (8)
  • 14.7: Superposition and Interference (6)
  • 14.8: Standing Waves (6)
  • 14.9: Beats (17)
  
  
• Chapter 15: Fluids
  • 15.1: Density (3)
  • 15.2: Pressure (4)
  • 15.3: Static Equilibrium in Fluids: Pressure and Depth (9)
  • 15.4: Achimedes' Principle and Bouyancy (3)
  • 15.5: Applications of Archimedes' Principle (6)
  • 15.6: Fluid Flow and Continuity (5)
  • 15.7: Bernoulli's Equation (3)
  • 15.8: Applications and Bernoulli's Equation (3)
  • 15.9: Viscosity and Surface Tension (18)
  
  
• Chapter 16: Temperature and Heat
  • 16.1: Temperature and the Zeroth Law of Thermodynamics
  • 16.2: Temperature Scales (4)
  • 16.3: Thermal Expansion (6)
  • 16.4: Heat and Mechanical Work (3)
  • 16.5: Specific Heats (7)
  • 16.6: Conduction, Convection, and Radiation (23)
  
  
• Chapter 17: Phase and Phase Changes
  • 17.1: Ideal Gases (10)
  • 17.2: Kinetic Theory (6)
  • 17.3: Solids and Elastic Deformation (7)
  • 17.4: Phase Equilibrium and Evaporation (6)
  • 17.5: Latent Heats (6)
  • 17.6: Phase Changes and Energy Conservation (11)
  
  
• Chapter 18: The Laws of Thermodynamics
  • 18.1: The Zeroth Law of Thermodynamics
  • 18.2: The First Law of Thermodynamics (7)
  • 18.3: Thermal Processes (13)
  • 18.4: Specific Heats for Ideal Gases: Constant Pressure, Constant Volume (6)
  • 18.5: The Second Law of Thermodynamics
  • 18.6: Heat Engines and the Carnot Cycle (9)
  • 18.7: Refrigerators, Air Conditioners, and Heat Pumps (4)
  • 18.8: Entropy (17)
  • 18.9: Order, Disorder, and Entropy
  • 18.10: The Third Law of Thermodynamics
  
  
• Chapter 19: Electric Charges, Forces, and Fields
  • 19.1: Electric Charge (4)
  • 19.2: Insulators and Conductors
  • 19.3: Coulomb's Law (15)
  • 19.4: The Electric Field (7)
  • 19.5: Electric Field Lines (3)
  • 19.6: Shielding and Charging by Induction
  • 19.7: Electric Flux and Gauss's Law (17)
  
  
• Chapter 20: Electric Potential Energy and Electric Potential
  • 20.1: Electric Potential Energy and Electric Potential (10)
  • 20.2: Energy Conservation (2)
  • 20.3: The Electric Potential of Point Charges (8)
  • 20.4: Equipotential Surfaces and the Electric Field (1)
  • 20.5: Capacitors and Dielectrics (8)
  • 20.6: Electrical Energy Storage (22)
  
  
• Chapter 21: Electric Current and Direct-Current Circuits
  • 21.1: Electric Current (2)
  • 21.2: Resistance and Ohm's Law (6)
  • 21.3: Energy and Power in Electric Circuits (3)
  • 21.4: Resistors in Series and Parallel (13)
  • 21.5: Kirchhoff's Rules (4)
  • 21.6: Circuits Containing Capacitors (5)
  • 21.7: RC Circuits (20)
  • 21.8: Ammeters and Voltmeters
  
  
• Chapter 22: Magnetism
  • 22.1: The Magnetic Field
  • 22.2: The Magnetic Force on Moving Charges (8)
  • 22.3: The Motion of Charges Particles in a Magnetic Field (6)
  • 22.4: The Force Extended on a Current-Carrying Wire (5)
  • 22.5: Loops of Current and Magnetic Torque (3)
  • 22.6: Electric Current, Magnetic Fields, and Ampere's Law (5)
  • 22.7: Current Loops and Solenoids (23)
  • 22.8: Magnetism in Matter
  
  
• Chapter 23: Magnetic Flux
  • 23.1: Induced Electromotive Force
  • 23.2: Magnetic Flux (4)
  • 23.3: Faraday's Law of Induction (3)
  • 23.4: Lenz's Law (6)
  • 23.5: Mechanical Work and Electrical Energy (5)
  • 23.6: Generators and Motors (3)
  • 23.7: Inductance (4)
  • 23.8: RL Circuits (3)
  • 23.9: Energy Stored in a Magnetic Field (5)
  • 23.10: Transformers (15)
  
  
• Chapter 24: Alternating-Current Circuits
  • 24.1: Alternating Voltages and Currents (2)
  • 24.2: Capacitors in an AC Circuit (7)
  • 24.3: RC Circuits (4)
  • 24.4: Inductors in AC Circuits (7)
  • 24.5: RLC Circuits (9)
  • 24.6: Resonance in Electrical Circuits (20)
  
  
• Chapter 25: Electromagnetic Waves
  • 25.1: The Production of Electromagnetic Waves (3)
  • 25.2: The Propagation of Electromagnetic Waves (10)
  • 25.3: The Electromagnetic Spectrum (5)
  • 25.4: Energy and Momentum in Electromagnetic Waves (16)
  • 25.5: Polarization (24)
  
  
• Chapter 26: Geometrical Optics
  • 26.1: The Reflection of Light (3)
  • 26.2: Forming Images with a Plane Mirror (5)
  • 26.3: Spherical Mirrors (2)
  • 26.4: Ray Tracing and Mirror Equation (10)
  • 26.5: The Refraction of Light (14)
  • 26.6: Ray Tracing for Lenses
  • 26.7: The Thin-Lens Equation (9)
  • 26.8: Dispersion and the Rainbow (17)
  
  
• Chapter 27: Optical Instruments
  • 27.1: The Human Eye and the Camera (5)
  • 27.2: Lenses in Combination and Corrective Optics (21)
  • 27.3: The Magnifying Glass (6)
  • 27.4: The Compound Microscope (6)
  • 27.5: Telescopes (18)
  • 27.6: Lens Aberrations
  
  
• Chapter 28: Physical Optics: Interference and Diffraction
  • 28.1: Superposition and Interference (6)
  • 28.2: Young's Two-Slit Experiment (9)
  • 28.3: Interference in Reflected Waves (6)
  • 28.4: Diffraction (7)
  • 28.5: Resolution (5)
  • 28.6: Diffraction Gratings (17)
  
  
• Chapter 29: Relativity
  • 29.1: The Postulates of Special Relativity
  • 29.2: The Relativity of Time and Time Dilation (9)
  • 29.3: The Relativity of Length and Length Contraction (7)
  • 29.4: The Relativistic Addition of Velocities (6)
  • 29.5: Relativistic Momentum and Mass (4)
  • 29.6: Relativistic Energy and E = mc² (11)
  • 29.7: The Relativistic Universe
  • 29.8: General Relativity (15)
  
  
• Chapter 30: Quantum Physics
  • 30.1: Blackbody Radiation and Planck's Hypothesis of Quantized Energy (3)
  • 30.2: Photons and the Photoelectric Effect (13)
  • 30.3: The Mass and Momentum of a Photon (6)
  • 30.4: Photon Scattering and the Compton Effect (5)
  • 30.5: The de Broglie Hypothesis and Wave-Particle Duality (5)
  • 30.6: The Heisenberg Uncertainty Principle (20)
  • 30.7: Quantum Tunneling
  
  
• Chapter 31: Atomic Physics
  • 31.1: Early Models of the Atom (2)
  • 31.2: The Spectrum of Atomic Hydrogen (4)
  • 31.3: Bohr's Model of the Hydrogen Atom (13)
  • 31.4: de Broglie Waves and the Bohr Model (2)
  • 31.5: The Quantum Mechanical Hydrogen Atom (5)
  • 31.6: Multielectron Atoms and the Periodic Table (1)
  • 31.7: Atomic Radiation (16)
  
  
• Chapter 32: Nuclear Physics and Nuclear Radiation
  • 32.1: The Constituents and Structure Nuclei (5)
  • 32.2: Radioactivity (5)
  • 32.3: Half-Life and Radioactive Decay (9)
  • 32.4: Nuclear Binding Energy (3)
  • 32.5: Nuclear Fission (3)
  • 32.6: Nuclear Fusion (2)
  • 32.7: Practical Applications of Nuclear Physics (20)
  • 32.8: Elementary Particles
  • 32.9: Unified Forces and Cosmology