Physics Physics of Everyday Phenomena
Physics of Everyday Phenomena

Physics of Everyday Phenomena Griffith • 9th Edition • 978-1259894008

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Ch. 01: Physics, the Fundamental Science

Introduction to Units Unit Conversions Solving Density Problems Dimensional Analysis Counting Significant Figures Operations with Significant Figures

Ch. 02: Describing Motion

Vectors, Scalars, & Displacement Average Velocity Intro to Acceleration Position-Time Graphs & Velocity Conceptual Problems with Position-Time Graphs Velocity-Time Graphs & Acceleration Calculating Displacement from Velocity-Time Graphs Conceptual Problems with Velocity-Time Graphs Calculating Change in Velocity from Acceleration-Time Graphs Graphing Position, Velocity, and Acceleration Graphs Kinematics Equations Catch/Overtake Problems

Ch. 03: Falling Objects and Projectile Motion

Vertical Motion and Free Fall Intro to Motion in 2D: Position & Displacement Velocity in 2D Acceleration in 2D Kinematics in 2D Intro to Projectile Motion: Horizontal Launch Negative (Downward) Launch Symmetrical Launch Positive (Upward) Launch Projectiles Launched From Moving Vehicles Special Equations in Symmetrical Launches Using Equation Substitution

Ch. 04: Newton's Laws: Explaining Motion

Newton's First & Second Laws Forces & Kinematics Vertical Forces & Acceleration Vertical Equilibrium & The Normal Force Newton's Third Law & Action-Reaction Pairs Forces in 2D Equilibrium in 2D Inclined Planes Kinetic Friction Static Friction Inclined Planes with Friction Forces in Connected Systems of Objects

Ch. 05: Circular Motion, the Planets, and Gravity

Circular Motion Rotational Position & Displacement Rotational Velocity & Acceleration Equations of Rotational Motion Converting Between Linear & Rotational Types of Acceleration in Rotation Rolling Motion (Free Wheels) Intro to Connected Wheels More Connect Wheels (Bicycles) Centripetal Forces Newton's Law of Gravity Gravitational Forces in 2D Acceleration Due to Gravity Gravitational Potential Energy Escape Velocity Satellite Motion: Intro Overview of Kepler's Laws Kepler's First Law Kepler's Third Law Satellite Motion: Speed & Period Geosynchronous Orbits

Ch. 06: Energy and Oscillations

Intro to Energy Intro to Calculating Work Work By Gravity & Inclined Planes Work By Variable Forces (Springs) Net Work & Kinetic Energy More Work-Energy Problems Power Centripetal Forces: Quick Intro Motion Along Curved Paths Solving Projectile Motion Using Energy Escape Velocity Intro to Conservation of Energy Energy with Non-Conservative Forces Conservative Forces & Inclined Planes Energy in Connected Objects (Systems) Springs & Elastic Potential Energy Spring Force (Hooke's Law) Intro to Simple Harmonic Motion (Horizontal Springs) Energy in Simple Harmonic Motion Simple Harmonic Motion of Vertical Springs Simple Harmonic Motion of Pendulums Energy in Pendulums

Ch. 07: Momentum and Impulse

Intro to Momentum Intro to Impulse Impulse with Variable Forces Intro to Conservation of Momentum Push-Away Problems Adding Mass to a Moving System How to Identify the Type of Collision Inelastic Collisions 2D Collisions Newton's Second Law and Momentum Momentum & Impulse in 2D Push-Away Problems With Energy Elastic Collisions Collisions & Motion (Momentum & Energy) Collisions with Springs

Ch. 08: Rotational Motion of Solid Objects

Intro to Torque Net Torque & Sign of Torque Torque on Discs & Pulleys How to Solve: Energy vs Torque Torque Due to Weight Torque & Acceleration (Rotational Dynamics) Intro to Center of Mass Torque & Equilibrium Equilibrium with Multiple Objects Equilibrium with Multiple Supports Center of Mass & Simple Balance Equilibrium in 2D - Ladder Problems Beam / Shelf Against a Wall Review: Center of Mass More 2D Equilibrium Problems Intro to Rotational Kinetic Energy Types of Motion & Energy Energy of Rolling Motion Conservation of Energy with Rotation More Conservation of Energy Problems Conservation of Energy in Rolling Motion Moment of Inertia & Mass Distribution Intro to Moment of Inertia Moment of Inertia of Systems Parallel Axis Theorem Moment of Inertia via Integration Torque with Kinematic Equations Rotational Dynamics with Two Motions Rotational Dynamics of Rolling Motion Angular Momentum & Newton's Second Law Opening/Closing Arms on Rotating Stool Conservation of Angular Momentum Jumping Into/Out of Moving Disc Spinning on String of Variable Length Intro to Angular Collisions Angular Collisions with Linear Motion Intro to Angular Momentum Angular Momentum of a Point Mass Angular Momentum of Objects in Linear Motion Conservation of Angular Momentum

Ch. 09: The Behavior of Fluids

Density Intro to Pressure Pascal's Law & Hydraulic Lift Pressure Gauge: Barometer Pressure Gauge: Manometer Pressure Gauge: U-shaped Tube Buoyancy & Buoyant Force Ideal vs Real Fluids Fluid Flow & Continuity Equation

Ch. 10: Temperature and Heat

Temperature Zeroth Law of Thermodynamics Thermal Expansion Introduction to Heat Calorimetry Changes in Temperature & Specific Heat Changes in Phase & Latent Heat Heat Transfer Introduction to Ideal Gasses Kinetic Theory of Gasses Internal Energy Introduction to Heat Capacity First Law of Thermodynamics

Ch. 11: Heat Engines and the Second Law of Thermodynamics

Thermal Processes Carnot Cycle Refrigerators Entropy and the Second Law Statistical Interpretation of Entropy

Ch. 12: Electrostatic Phenomena

Electric Charge Charging Objects Charging By Induction Conservation of Charge Coulomb's Law (Electric Force) Electric Field Electric Field Lines Electric Fields in Conductors Electric Flux Gauss' Law Electric Potential Energy Electric Potential Work From Electric Force Relationships Between Force, Field, Energy, Potential The ElectronVolt Equipotential Surfaces

Ch. 13: Electric Circuits

Intro to Current Resistors and Ohm's Law Power in Circuits Microscopic View of Current Combining Resistors in Series & Parallel Alternating Voltages and Currents RMS Current and Voltage Power in AC Circuits Phasors Resistors in AC Circuits Phasors for Resistors

Ch. 14: Magnets and Electromagnetism

Magnets and Magnetic Fields Summary of Magnetism Problems Force on Moving Charges & Right Hand Rule Circular Motion of Charges in Magnetic Fields Mass Spectrometer Magnetic Force on Current-Carrying Wire Force and Torque on Current Loops Magnetic Field Produced by Moving Charges Magnetic Field Produced by Straight Currents Magnetic Force Between Parallel Currents Magnetic Force Between Two Moving Charges Magnetic Field Produced by Loops and Solenoids Intro to Induction Magnetic Flux Faraday's Law Lenz's Law Motional EMF Mutual Inductance Self Inductance Inductors LR Circuits

Ch. 15: Making Waves

What is a Wave? The Mathematical Description of a Wave Waves on a String Wave Interference Standing Waves Sound Waves Standing Sound Waves Sound Intensity The Doppler Effect Beats

Ch. 16: Light Waves and Color

What is an Electromagnetic Wave? Electromagnetic Waves as Sinusoidal Waves The Electromagnetic Spectrum Diffraction 36.02 (A, n/a): Diffraction with Huygen's Principle Young's Double Slit Experiment Single Slit Diffraction Polarization Filters

Ch. 17: Light and Image Formation

Ray Nature Of Light Reflection Of Light Refraction Of Light Total Internal Reflection Ray Diagrams For Mirrors Mirror Equation Refraction At Spherical Surfaces Ray Diagrams For Lenses Thin Lens And Lens Maker Equations

Ch. 18: The Structure of the Atom

Atomic Structure Quantum Mechanics Particle-Wave Duality

Ch. 19: The Nucleus and Nuclear Energy

Nuclear Physics Particle Physics

Ch. 20: Relativity

Inertial Reference Frames Special Vs. Galilean Relativity Consequences of Relativity Lorentz Transformations