Charge Interactions Video Transcript

TPC and eLearning
What's NEW at TPC?
Read Watch Interact
Physics Tutorial
- 1-D Kinematics
- Newton's Laws
- Vectors - Motion and Forces in Two Dimensions
- Momentum and Its Conservation
- Work and Energy
- Circular Motion and Satellite Motion
- Thermal Physics
- Static Electricity
- Electric Circuits
- Vibrations and Waves
- Sound Waves and Music
- Light and Color
- Reflection and Mirrors
- Refraction and Lenses
Physics Interactives
- About the Physics Interactives
- Task Tracker
- Usage Policy
- Kinematics
- Newtons Laws
- Vectors and Projectiles
- Forces in 2D
- Momentum and Collisions
- Work and Energy
- Circular and Satellite Motion
- Balance and Rotation
- Fluids
- Static Electricity
- Electric Circuits
- Electromagnetism
- Waves and Sound
- Light and Color
- Reflection and Mirrors
- Refraction and Lenses
- Atomic Physics
- Chemistry
Video Tutorial
- Kinematics
- Newton's Laws
- Vectors and Projectiles
- Forces in Two Dimensions
- Momentum and Collisions
- Work, Energy, and Power
- Circular Motion and Gravitation
- Static Electricity
- Electric Circuits
- Vibrations and Waves
- Sound Waves
- Light and Color
- Reflection and Mirrors
- Refraction and Lenses
Multimedia Studios
- 1-Dimensional Kinematics
- Newton's Laws
- Vectors and Projectiles
- Momentum and Collisions
- Work and Energy
- Circular, Satellite, and Rotational Motion
- Einstein's Theory of Special Relativity
- Static Electricity
- Waves, Sound and Light
- Ray Optics
- QuickTime Movies
Practice Review Test
Concept Builders
- About the Concept Builders
- Version 2
- Pricing For Schools
- Directions for Version 2
- Measurement and Units
- Relationships and Graphs
- Kinematics
- Newton's Laws
- Vectors and Projectiles
- Forces in 2-Dimensions
- Momentum and Collisions
- Work and Energy
- Circular and Satellite Motion
- Rotation and Balance
- Fluids
- Static Electricity
- Electric Circuits
- Vibrational Motion
- Waves and Sound
- Light and Color
- Reflection and Refraction
- Chemistry
Minds On Physics
- About MOPs
- Features
- Teacher Accounts
- Pricing For Schools
- Task Tracker Directions
- Kinematic Concepts
- Kinematic Graphing
- Newton's Laws
- Vectors and Projectiles
- Forces in 2-Dimensions
- Momentum and Collisions
- Work and Energy
- Circular and Satellite Motion
- Static Electricity
- Electric Circuits
- Wave Motion
- Sound and Music
- Light and Color
- Reflection and Mirrors
- Refraction and Lenses
Calculator Pad
- About CalcPad
- Teacher Accounts
- Pricing For Schools
- Directions
- 1D Kinematics
- Newton's Laws
- Vectors and Projectiles
- Vectors and Forces in 2D
- Momentum and Collisions
- Work, Energy, and Power
- Circular Motion and Gravitation
- Simple Harmonic Motion
- Rotational Kinematics
- Rotation and Torque
- Rotational Dynamics
- Fluids
- Static Electricity
- Electric Fields, Potential, and Capacitance
- Electric Circuits
- Transient RC Circuits
- Electromagnetism
- Vibrations and Waves
- Sound Waves
- Light Waves
- Reflection and Mirrors
- Refraction and Lenses
- Units and Measurement
- Mole Conversions
- Stoichiometry
- Molarity and Solutions
- Gas Laws
- Thermal Chemistry
- Acids and Bases
- Kinetics and Equilibrium
- Solution Equilibria
- Oxidation-Reduction
- Nuclear Chemistry
Concept Checkers
- About Concept Checkers
- Teacher Accounts
- School Pricing
- Task Tracker Directions
Reasoning Center
- Task Tracker
- NGSS Alignments
- 1D-Kinematics
- Newton's Laws
- Projectiles
- Momentum
- Energy
- Circular Motion
- Static Electricity
- Circuits
- Magnetism and Electromagnetism
- Thermal Physics
- Waves
- Sound Waves
- Light Waves
- Reflection and Mirrors
- Refraction and Lenses
- Chemistry
Physics Help
- Graphing Practice
- Recognizing Forces
- Vector Direction
- Vector Addition
ACT Test Center
- About the ACT
- ACT Preparation
- ACT Tips
- For Teachers
- Other Resources
Teacher-Tools
The Review Session
- 1-D Kinematics
- Newton's Laws of Motion
- Vectors and Projectiles
- Forces in Two Dimensions
- Momentum and Collisions
- Work and Energy Packet
- Circular Motion and Gravitation
- Static Electricity Review
- Electric Circuits
- Waves
- Sound and Music
- Light and Color
- Reflection and Mirrors
- Refraction and Lenses
Curriculum Corner
- Solutions Guide
- Solutions Guide Digital Download
- Usage Policy
- Motion in One Dimension
- Newton's Laws
- Vectors and Projectiles
- Forces in Two Dimensions
- Momentum and Collisions
- Work, Energy and Power
- Circular Motion and Gravitation
- Static Electricity
- Electric Circuits
- Wave Basics
- Sound and Music
- Light and Color
- Reflection and Mirrors
- Refraction and Lenses
Lesson Plans
- About
- TaskTracker
- Other Tools
- Algebra Based Physics
- Frequently Asked Questions
- Purchasing the Download
Teacher Pres'n Pack
- Contents
- Frequently Asked Questions
- Purchasing the Download
Question Bank
- Contents
- Purchasing the CD
- Purchasing the Digital Download
NGSS Corner
- About the NGSS Corner
- NGSS Search
- Force and Motion DCIs - High School
- Energy DCIs - High School
- Wave Applications DCIs - High School
- Force and Motion PEs - High School
- Energy PEs - High School
- Wave Applications PEs - High School
- Crosscutting Concepts
- The Practices
- Physics Topics
- NGSS Corner: Activity List
- NGSS Corner: Infographics
Teacher Toolkits
- About the Toolkits
- Position-Velocity-Acceleration
- Position-Time Graphs
- Velocity-Time Graphs
- Free Fall
- Newton's First Law
- Newton's Second Law
- Newton's Third Law
- Terminal Velocity
- Vectors
- Projectile Motion
- Forces in 2 Dimensions
- Impulse and Momentum Change
- Momentum Conservation
- Work-Energy Fundamentals
- Work-Energy Relationship
- Circular Motion
- Roller Coaster Physics
- Universal Gravitation
- Satellite Motion
- Charge and Charging
- Coulombs Law
- Electric Fields
- Circuit Concepts
- Series Circuits
- Parallel Circuits
- Vibrational Motion
- Describing-Waves
- Wave Behavior Toolkit
- Standing Wave Patterns
- Sound Waves
- Resonating Air Columns
- Wave Model of Light
- Color
- Plane Mirrors
- Curved Mirrors
- Snells Law
- Total Internal Reflection
- Lenses
The Laboratory
- About
- Teacher Guide
- Using Lab Notebooks
- Share
The Photo Gallery
- 1-D Kinematics
- Newton's Laws
- Vectors - Motion and Forces in Two Dimensions
- Momentum and Its Conservation
- Work, Energy, and Power
- Circular Motion and Satellite Motion
- Thermal Physics
- Static Electricity
- Current Electricity
- Waves
- Sound Waves and Music
- Light Waves and Color
- Reflection and Ray Model of Light
- Refraction and Ray Model of Light
Store
- Subscription Selection
- Seat Calculator
- Ad Free Account
- My Cart
Task Tracker
- Edit Profile Settings
- Classes (Version 2)
- Classes (Legacy Version)
- Teacher Resources
- Tasks and Classes
- Tasks - Classic
- Subscriptions
- Subscription Locator

The Physics Classroom » Concept Builders » Static Electricity » Getting the Hang of Charge » Charge Interactions Video » Transcript

Charge Interactions

We provide the transcript below to those who for whatever reason would find the written words to be preferred over or in addition to the actual video.

You may view the video below or on YouTube.

Also available:
Charge Interactions Video || Video Notes || Full-Length Tutorial Video

Charge Interactions

Video Transcript

Charged objects interact with other objects in their surroundings. By observing these interactions, you can often predict the type of charge an object possesses. To do so, apply three simple rules of charge interactions:
First, like-charged objects repel each other.
Second, oppositely-charged objects attract each other.
And third, any charged object, whether + or -, and a neutral object will attract each other.

Notice that “attract each other” appears twice on our list. So if two objects are attracting each other, there are two possible explanations: either they are both charged with opposite charge types – one positive, the other negative. Or one of the objects is charged and the other is neutral. More observations are required to determine which explanation applies.
Let’s mix “rules” 1, 2, and 3 with some logical reasoning to do four examples.

Example 1: We know balloon X is + and balloons X and Y repel. Balloons Y and Z also repel. What is the charge on balloons Y and Z? Like charges repel (Rule 1). So if X is + then Y must be +. Since Y and Z repel, they too must be like-charged (Rule 1). So Z is also +.

Example 2: We know X is + and X and Y attract. Opposites attact (Rule 2) so Y could be –. But a charged and neutral also attract (Rule 3), so Y could also be neutral. But then we observe that Y and Z repel. Only charged objects repel (Rule 1) so Y can’t be neutral. Y is – so Z is also –.

Example 3: We know X is + and X and Y attract. So Y is either – (Rule 2) or neutral (Rule 3). Balloons Y and Z also attract but we have limited knowledge about Y. If Y is -, then Z could be + (Rule 2) or neutral (Rule 3). But Y could also be neutral; and Z would attract a neutral if it were + or – (Rule 3).

Example 4: We know X is + and X and Y attract. Balloons Y and Z also attract. And balloon Y attracts neutral paper bits. There are three Y observations. Y’s interactions with paper bits indicates Y is charged. Since Y and X attract, we know Y is – (Rule 2). Finally, since Y and Z attract, Z is either + (Rule 2) or neutral (Rule 3).

These four examples illustrate how logic and three simple rules about charge interactions allow you to predict the charges on objects. I’m Mr. H, letting you know that … You got this!

Visit: Concept Builder || Teacher Notes || Directions || Questions (For Teachers Only)