Presentation is loading. Please wait.

Presentation is loading. Please wait.

Today 3/10  Plates if charge  E-Field  Potential  HW:“Plates of Charge” Due Thursday, 3/13  Lab: “Electric Deflection of Electrons”

Published byEdwin Crawford Modified over 9 years ago

Similar presentations

Presentation on theme: "Today 3/10  Plates if charge  E-Field  Potential  HW:“Plates of Charge” Due Thursday, 3/13  Lab: “Electric Deflection of Electrons”"— Presentation transcript:

1 Today 3/10  Plates if charge  E-Field  Potential  HW:“Plates of Charge” Due Thursday, 3/13  Lab: “Electric Deflection of Electrons”

2 ++++++++++++++++++ Looking from farther away

3 +++++ We call this an “infinite plate.”

4 Field lines for a positive plate  (+)  is the charge on each square meter of the plate. Near the plate the field lines must (by symmetry) point directly away from the plate. How does the field strength at the X’s compare? Same field line density, same strength!

5  (+) Field lines for a plate

6  (-) Field lines for a negative plate Can’t tell if the field is caused by a pos plate below or a neg plate above!

7 Size of the E-field For plates: For point charges:  0 = 8.8x10 -12 C 2 /Nm 2 k = 9.0x10 9 Nm 2 /C 2 Note: no dependence on distance

8 Two Parallel Plates  (+)  (-)

9  (+) Two Parallel Plates  (-)

10  (+) Two Parallel Plates  (-) E net

11  (+) Two Parallel Plates  (-) E net

12  (+) Two Parallel Plates  (-) E net E net = 0

13  (+) How big is E?  (-) E net

14  (+) How big is E?  (-) E net = 0

15  (+) What do the field lines look like?  (-) E = 0 outside!

16 a. The field at A drops more than the field at B. b. The field at B drops more than the field at A. c. The fields at A and B remain that same. d. The fields at A and B drop by the same amount. AB +Q -Q Points A and B are located as shown between two large uniformly charged parallel plates. Which of the following correctly describes what happens to the electric fields at A and B if the plate on the right is removed?

17  0 = Q/A Charged conducting plate What’s wrong with this picture? A = Area of one side

18  L =  0 /2 Charged conducting plate Free charge always goes to surface of conductor.  R =  0 /2

19  L =  0 /2 Charged conducting plate  R =  0 /2 What is the electric field inside the conductor? E L =  L /2  0 E L =  0 /4  0

20  L =  0 /2 Charged conducting plate  R =  0 /2 What is the electric field inside the conductor? E R =  R /2  0 E R =  0 /4  0

21  L =  0 /2 Charged conducting plate  R =  0 /2 What is the electric field inside the conductor? The electric field is zero everywhere inside the conductor.

Download ppt "Today 3/10  Plates if charge  E-Field  Potential  HW:“Plates of Charge” Due Thursday, 3/13  Lab: “Electric Deflection of Electrons”"

Similar presentations

Coulomb law.

Coulomb law.
Announcements Monday guest lecturer: Dr. Fred Salsbury. Solutions now available online. Will strive to post lecture notes before class. May be different.

Announcements Monday guest lecturer: Dr. Fred Salsbury. Solutions now available online. Will strive to post lecture notes before class. May be different.
IB 5.2 Electric Field & Potential

IB 5.2 Electric Field & Potential
…and all the pretty variations… F = k q 1 q 2 r2r2 E = k q 1 r2r2 U = k q 1 q 2 r V = k q 1 r.

…and all the pretty variations… F = k q 1 q 2 r2r2 E = k q 1 r2r2 U = k q 1 q 2 r V = k q 1 r.
Rank the electric fluxes through each Gaussian surface shown in the figure from largest to smallest. Display any cases of equality in your ranking.

Rank the electric fluxes through each Gaussian surface shown in the figure from largest to smallest. Display any cases of equality in your ranking.
Chapter 21 Reading Quiz Dr. Harold Williams.

Chapter 21 Reading Quiz Dr. Harold Williams.
Applications of Gauss’s Law

Applications of Gauss’s Law
Ch. 24 Electric Flux Gauss's Law

Ch. 24 Electric Flux Gauss's Law
Today 3/12  Plates if charge  E-Field  Potential  HW:“Plate Potential” Due Friday, 3/14.

Today 3/12  Plates if charge  E-Field  Potential  HW:“Plate Potential” Due Friday, 3/14.
Halliday/Resnick/Walker Fundamentals of Physics 8th edition

Halliday/Resnick/Walker Fundamentals of Physics 8th edition
Sign Conventions Electrical Potential E avg =  V/d  V = E d It would be logical to set up a sign convention where  V is + when a + test charge gains.

Sign Conventions Electrical Potential E avg =  V/d  V = E d It would be logical to set up a sign convention where  V is + when a + test charge gains.
Physics 2112 Unit 6: Electric Potential

Physics 2112 Unit 6: Electric Potential
Electric Field Physics 102 Professor Lee Carkner Lecture 11.

Electric Field Physics 102 Professor Lee Carkner Lecture 11.
Lecture 4: Conductors Forces on charges and torques on dipoles.

Lecture 4: Conductors Forces on charges and torques on dipoles.
Gauss’s Law PH 203 Professor Lee Carkner Lecture 5.

Gauss’s Law PH 203 Professor Lee Carkner Lecture 5.
A Charged, Thin Sheet of Insulating Material + + + + + + + + + + +

A Charged, Thin Sheet of Insulating Material
If I put no excess charge on the conductor, the net charge on its inner surface will be: a] 0 b] +Q c] -Q d] -2Q e] cannot determine.

If I put no excess charge on the conductor, the net charge on its inner surface will be: a] 0 b] +Q c] -Q d] -2Q e] cannot determine.
A Charged, Thin Sheet of Insulating Material + + + + + + + + + + +

A Charged, Thin Sheet of Insulating Material
Topic 9.3 Electric Field, Potential, and Energy

Topic 9.3 Electric Field, Potential, and Energy
Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley. Electric potential energy Electric potential Conservation of energy Chapter.

Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley. Electric potential energy Electric potential Conservation of energy Chapter.

Similar presentations

Ads by Google