AP Physics 1 and 2 Essentials - Complete Curriculum Framework

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Explore the complete AP Physics 1 & 2 curriculum through this comprehensive video series that covers all essential knowledge from the 2014-2015 framework. Master fundamental concepts starting with systems and objects, including particles, atomic structure, electric charge, and mass-energy relationships. Delve into wave-particle duality, spacetime, and material properties like density, resistivity, and magnetic permeability. Study vector and scalar fields, gravitational and electromagnetic forces, and learn to analyze electric fields of spheres, dipoles, and parallel plates. Examine magnetic forces, fields, and domains while working with contour and equipotential lines. Understand motion through forces, Newton's laws, simple harmonic motion, and free-body diagrams. Investigate momentum, impulse, work-energy principles, torque, and angular momentum. Analyze gravitational, electromagnetic, and nuclear forces while exploring rotational motion and center of mass calculations. Apply conservation laws to energy systems, including kinetic, potential, and internal energy, along with thermodynamics and P-V diagrams. Study electromagnetic induction, electric circuits, resistors, capacitors, and Kirchhoff's rules. Explore wave properties including mechanical and electromagnetic waves, amplitude, frequency, wavelength, Doppler effect, interference, diffraction, and standing waves. Examine light behavior through reflection, refraction, ray diagrams for mirrors and lenses, and electromagnetic radiation. Understand photons and wave-particle duality of both light and matter. Conclude with gas pressure, kinetic theory, ideal gas law, thermodynamic principles, quantum wave functions, electron models, radioactive decay, and stimulated emission concepts essential for AP Physics success.

Syllabus

Systems and Objects
Fundamental Particles
Atomic Nucleus
The Bohr Atom
Objects
Electric Charge
Positive and Negative Charge
Elementary Charge
Inertial Mass
Gravitational Mass
Equivalence Principle
E=mc2
Wave-Particle Duality - Part 1
Wave-Particle Duality - Part 2
Spacetime
Density
Resistivity
Thermal Conductivity
Electric Permittivity
Magnetic Permeability
Magnetic Dipole Moment
Vector Field
Scalar Field
Gravitational Force
Gravitational Field Strength
Electric Force
Electric Field Strength
Electric Field of a Sphere
Electric Field of a Dipole
Electric Field of Parallel Plates
Magnetic Force
Magnetic Field of a Wire
Magnetic Field of a Dipole
Magnetic Domains
Contour Lines
Equipotential Lines
Average Value of the Electric Field
Motion
Forces
Interaction Forces
Newton's Third Law
Vector Sum of Forces
Free-Body Diagrams
Simple Harmonic Motion
Calculating the Gravitational Force
Calculating the Electric Force
Measuring the Magnetic Force
Contact Forces
Momentum
Impulse
Work Energy Principle
Torque
Rotational Motion
Angular Momentum
Gravitational Forces
Electromagnetic Forces
Strong Nuclear Force
Motion of the Center of Mass
Position, Velocity and Acceleration
Newton's Second Law
Linear Momentum
Force-Time Graph
Total Energy
Work and Energy
Heating
Mass and Energy
The Vector Properties of Angular Quantities
Angular Momentum of a System
Angular Impulse
Magnetic Properties
Electromagnetic Induction
Electrostatic Induction
Resistors and Capacitors
Electric Circuits
Systems
Conservation Laws
Object Interactions
System Boundaries
Kinetic Energy
Internal Energy
Potential Energy
Kinetic and Potential Energy
Work and Power
Heat
Thermodynamics and P-V Diagrams
Emission and Absorption Spectra
Kirchoff's Loop Rule
Bernoulli's Equation
Energy-Mass Equivalence
Conservation of Charge in Reactions
Conservation of Electric Charge
Kirchhoff's Junction Rule
Conservation of Linear Momentum
Elastic and Inelastic Collisions
Center of Mass
Conservation of Angular Momentum
Rotational Inertia
Continuity Equation
Conservation of Nucleon Number
Transverse and Longitudinal Waves
Mechanical and Electromagnetic Waves
Wave Amplitude
Wave Energy
Wave Period and Frequency
Wavelength
Wave Equation
Wave Speed
Doppler Effect
Wave Interference
Wave Diffraction
Interference Patterns
Diffraction Effects
Wave Superposition
Traveling Waves
Standing Waves
Harmonics
Beats
Light Absorption, Reflection, and Transmission
Specular Reflection
Refraction of Light
Ray Diagrams - Mirrors
Ray Diagrams - Lenses
Electromagnetic Radiation
Electromagnetic Waves
Photons
Wave-Particle Duality of Light
Matter as a Particle
Matter as a Wave
Gas Pressure
Kinetic Theory and Temperature
Ideal Gas Law
Thermal Equlibrium
Second Law of Thermodynamics
Wave Function
Wave Model of an Electron
Half-Life and Radioactive Decay
Stimulated Emission