Presentation is loading. Please wait.

Presentation is loading. Please wait.

Lecture 1 agenda: Electric Charge. Just a reminder of some things you learned back in grade school. Coulomb’s Law (electrical force between charged particles).

Published byBrent Maxwell Modified over 8 years ago

Similar presentations

Presentation on theme: "Lecture 1 agenda: Electric Charge. Just a reminder of some things you learned back in grade school. Coulomb’s Law (electrical force between charged particles)."— Presentation transcript:

1 Lecture 1 agenda: Electric Charge. Just a reminder of some things you learned back in grade school. Coulomb’s Law (electrical force between charged particles). You must be able to calculate the electrical forces between one or more charged particles. The electric field. You must be able to calculate the force on a charged particle in an electric field. Electric field due to point charges. You must be able to calculate electric field of one or more point charges. Motion of a charged particle in a uniform electric field. You must be able to solve for the trajectory of a charged particle in a uniform electric field.

2 Motion of a Charged Particle in a Uniform Electric Field A charged particle in an electric field experiences a force, and if it is free to move, an acceleration. - - - - - - - - - - - - - + + + + + + + + + + + + + - F If the only force is due to the electric field, then If E is constant, then a is constant, and you can use the equations of kinematics* (remember way back to the beginning of Physics 1135?). *If you get called to the board, you can use the Physics 1135 starting equations. They are posted. E

3 Example: an electron moving with velocity v 0 in the positive x direction enters a region of uniform electric field that makes a right angle with the electron’s initial velocity. Express the position and velocity of the electron as a function of time. - - - - - - - - - - - - - + + + + + + + + + + + + + E x y -e v0v0 To be worked at the blackboard in lecture. What would be different for a proton? Make sure you understand what a uniform electric field is.

4 Express the position and velocity of the electron as a function of time. E x y v0v0 -e FEFE Let’s work the rest of the problem one component at a time. a

5 Express the position and velocity of the electron as a function of time. E x y v0v0 -e FEFE 00 0 0 Position: a

6 Express the position and velocity of the electron as a function of time. E x y v0v0 -e FEFE 0 0 Velocity: a

7 What is the shape of the electron’s path? E x y v0v0 -e FEFE a The trajectory of the electron is a parabola, concave down. Just like the trajectory of a ball thrown horizontally in the gravitational field of the Earth.

Download ppt "Lecture 1 agenda: Electric Charge. Just a reminder of some things you learned back in grade school. Coulomb’s Law (electrical force between charged particles)."

Similar presentations

Motion of Charged Particles in a Uniform Electric Field

Motion of Charged Particles in a Uniform Electric Field
Range, Height and Time.

Range, Height and Time.
Chapter 21 Electric Charge and Electric Field. Charles Allison © 2000 Question An  particle with a charge +2e and a mass of 4m p is on a collision course.

Chapter 21 Electric Charge and Electric Field. Charles Allison © 2000 Question An  particle with a charge +2e and a mass of 4m p is on a collision course.
Agenda 1) Warm-Up 5 min 2) Vocab. Words 10 min 3) Projectile Motion Intro. 15 min 4) Pre-Lab Vectors 15 min 5) Vector Lab 30 min 11-08-11 Spring scale.

Agenda 1) Warm-Up 5 min 2) Vocab. Words 10 min 3) Projectile Motion Intro. 15 min 4) Pre-Lab Vectors 15 min 5) Vector Lab 30 min Spring scale.
CH 19-3. Review -- Gravitational Potential Energy and Gravitational Potential Earth If a ball is released from rest, it will move in the direction of.

CH Review -- Gravitational Potential Energy and Gravitational Potential Earth If a ball is released from rest, it will move in the direction of.
NON NON – POLY ATTIRE, ID’s AROUND YOUR NECK OBJECTIVE` Be able to solve the x and y components of a vector. Drill 2.10: Drill 2.10: trig functions Date:

NON NON – POLY ATTIRE, ID’s AROUND YOUR NECK OBJECTIVE` Be able to solve the x and y components of a vector. Drill 2.10: Drill 2.10: trig functions Date:
Lecture 1 agenda: Electric Charge. Just a reminder of some things you learned back in grade school. Coulomb’s Law (electrical force between charged particles).

Lecture 1 agenda: Electric Charge. Just a reminder of some things you learned back in grade school. Coulomb’s Law (electrical force between charged particles).
Kinematics Motion Equations 1 Constant Acceleration Constant Acceleration Problem Solving Equations of Motion Centripetal and Tangential Acceleration Free-Fall.

Kinematics Motion Equations 1 Constant Acceleration Constant Acceleration Problem Solving Equations of Motion Centripetal and Tangential Acceleration Free-Fall.
Electrical Potential Energy Chapter 18.1. Electrical Potential Energy Electrical Potential Energy – Potential energy associated with an object due to.

Electrical Potential Energy Chapter Electrical Potential Energy Electrical Potential Energy – Potential energy associated with an object due to.
Electric Fields Electric fields are created by electric charges. Any object with a charge has an electric field around it. Opposite charges attract each.

Electric Fields Electric fields are created by electric charges. Any object with a charge has an electric field around it. Opposite charges attract each.
Chapter 22 Gauss’s Law. Charles Allison © 2000 21-10 Motion of a Charged Particle in an Electric Field The force on an object of charge q in an electric.

Chapter 22 Gauss’s Law. Charles Allison © Motion of a Charged Particle in an Electric Field The force on an object of charge q in an electric.
Projectile Motion Chapter 3 section 3.

Projectile Motion Chapter 3 section 3.
Today’s agenda: Magnetic Fields. You must understand the similarities and differences between electric fields and field lines, and magnetic fields and.

Today’s agenda: Magnetic Fields. You must understand the similarities and differences between electric fields and field lines, and magnetic fields and.
Accelerating Charge Through A Potential Difference.

Accelerating Charge Through A Potential Difference.
My Chapter 16 Lecture Outline.

My Chapter 16 Lecture Outline.
Free fall An object undergoing free fall has an acceleration of 9.8118m/s2 . This varies from the equator when it is 9.7803m/s2 to the poles when it.

Free fall An object undergoing free fall has an acceleration of m/s2 . This varies from the equator when it is m/s2 to the poles when it.
Magnetic Field Strength and Magnetic Force O An electrically charged particle moving in a magnetic field may experience a magnetic force. O Magnetic Field.

Magnetic Field Strength and Magnetic Force O An electrically charged particle moving in a magnetic field may experience a magnetic force. O Magnetic Field.
1 Chapter 6: Motion in a Plane. 2 Position and Velocity in 2-D Displacement Velocity Average velocity Instantaneous velocity Instantaneous acceleration.

1 Chapter 6: Motion in a Plane. 2 Position and Velocity in 2-D Displacement Velocity Average velocity Instantaneous velocity Instantaneous acceleration.
Chapter 4:Kinematics in Two Dimensions

Chapter 4:Kinematics in Two Dimensions
Introduction to Projectile Motion

Introduction to Projectile Motion

Similar presentations

Ads by Google