Presentation is loading. Please wait.

Presentation is loading. Please wait.

An insulating spherical shell has an inner radius b and outer radius c

Published byIda Budiaman Modified over 6 years ago

Similar presentations

Presentation on theme: "An insulating spherical shell has an inner radius b and outer radius c"— Presentation transcript:

1 An insulating spherical shell has an inner radius b and outer radius c
An insulating spherical shell has an inner radius b and outer radius c. The shell has a uniformly distributed total charge +Q. Concentric with the shell is a solid conducting sphere of total charge +2Q and radius a<b. Find the magnitude of the electric field for r<a. Use first and last slide for in-person lecture; delete for video lecture This looks like a test preparation homework problem, but it is different!

2 For 0<r<a, we are inside the conductor, so E=0. b a
An insulating spherical shell has an inner radius b and outer radius c. The shell has a uniformly distributed total charge +Q. Concentric with the shell is a solid conducting sphere of total charge +2Q and radius a<b. Find the magnitude of the electric field for r<a. +Q For 0<r<a, we are inside the conductor, so E=0. b a c If E=0 there is no need to specify a direction (and the problem doesn’t ask for one anyway). +2Q

3 An insulating spherical shell has an inner radius b and outer radius c
An insulating spherical shell has an inner radius b and outer radius c. The shell has a uniformly distributed total charge +Q. Concentric with the shell is a solid conducting sphere of total charge +2Q and radius a<b. Use Gauss’ Law to find the magnitude of the electric field for a<r<b. +Q b a r c +2Q Be able to do this: begin with a statement of Gauss’s Law. Draw an appropriate Gaussian surface on the diagram and label its radius r. Justify the steps leading to your answer.

4 An insulating spherical shell has an inner radius b and outer radius c
An insulating spherical shell has an inner radius b and outer radius c. The shell has a uniformly distributed total charge +Q. Concentric with the shell is a solid conducting sphere of total charge +2Q and radius a<b. Use Gauss’ Law to find the magnitude of the electric field for b<r<c. +Q b a +2Q r c

5 +Q b a +2Q r c The direction of is shown in the diagram. Solving for the magnitude E (do it!) is “just” math.

6 +Q b a +2Q r c What would be different if we had concentric cylinders instead of concentric spheres? What would be different if the outer shell were a conductor instead of an insulator?

7 An insulating spherical shell has an inner radius b and outer radius c
An insulating spherical shell has an inner radius b and outer radius c. The shell has a uniformly distributed total charge +Q. Concentric with the shell is a solid conducting sphere of total charge +2Q and radius a<b. Find the magnitude of the electric field for b<r<c. What would be different if we had concentric cylinders instead of concentric spheres? What would be different if the outer shell were a conductor instead of an insulator?

Download ppt "An insulating spherical shell has an inner radius b and outer radius c"

Similar presentations

QUICK QUIZ 24.1 (For the end of section 24.1)

QUICK QUIZ 24.1 (For the end of section 24.1)
Applications of Gauss’s Law

Applications of Gauss’s Law
Electric Potential AP Physics Montwood High School R. Casao.

Electric Potential AP Physics Montwood High School R. Casao.
Lecture 6 Problems.

Lecture 6 Problems.
Gauss’s law and its applications

Gauss’s law and its applications
© 2012 Pearson Education, Inc. A spherical Gaussian surface (#1) encloses and is centered on a point charge +q. A second spherical Gaussian surface (#2)

© 2012 Pearson Education, Inc. A spherical Gaussian surface (#1) encloses and is centered on a point charge +q. A second spherical Gaussian surface (#2)
C. less, but not zero. D. zero.

C. less, but not zero. D. zero.
Phy 213: General Physics III Chapter 23: Gauss’ Law Lecture Notes.

Phy 213: General Physics III Chapter 23: Gauss’ Law Lecture Notes.
Electricity Electric Flux and Gauss’s Law 1 Electric Flux Gauss’s Law Electric Field of Spheres Other Gaussian Surfaces Point Charges and Spheres.

Electricity Electric Flux and Gauss’s Law 1 Electric Flux Gauss’s Law Electric Field of Spheres Other Gaussian Surfaces Point Charges and Spheres.
A Charged, Thin Sheet of Insulating Material + + + + + + + + + + +

A Charged, Thin Sheet of Insulating Material
Average 68.4 Median 68.5 9080706050 Highest 100 Lowest 26 Section 807 57.6 Section 808 68 Section 809 68.6 Section 523 78.3.

Average 68.4 Median Highest 100 Lowest 26 Section Section Section Section
Slide 1 Electric Field Lines 10/29/08. Slide 2Fig 25-21, p.778 Field lines at a conductor.

Slide 1 Electric Field Lines 10/29/08. Slide 2Fig 25-21, p.778 Field lines at a conductor.
General Physics 2, Lec 5, By/ T.A. Eleyan 1 Additional Questions (Gauss’s Law)

General Physics 2, Lec 5, By/ T.A. Eleyan 1 Additional Questions (Gauss’s Law)
E The net electric flux through a closed cylindrical surface is zero.

E The net electric flux through a closed cylindrical surface is zero.
Today’s agenda: Announcements. Gauss’ Law Examples. You must be able to use Gauss’ Law to calculate the electric field of a high-symmetry charge distribution.

Today’s agenda: Announcements. Gauss’ Law Examples. You must be able to use Gauss’ Law to calculate the electric field of a high-symmetry charge distribution.
Example: calculate the electric field for 0

Example: calculate the electric field for 0
a b c Gauss’ Law … made easy To solve the above equation for E, you have to be able to CHOOSE A CLOSED SURFACE such that the integral is TRIVIAL. (1)

a b c Gauss’ Law … made easy To solve the above equation for E, you have to be able to CHOOSE A CLOSED SURFACE such that the integral is TRIVIAL. (1)
A b c Gauss' Law.

A b c Gauss' Law.
III.A 3, Gauss’ Law.

III.A 3, Gauss’ Law.
© 2012 Pearson Education, Inc. { Chapter 22 Applying Gauss’s Law.

© 2012 Pearson Education, Inc. { Chapter 22 Applying Gauss’s Law.

Similar presentations

Ads by Google