Presentation is loading. Please wait.

Presentation is loading. Please wait.

Wed. Feb. 25 – Physics Lecture #32 Faraday’s Law II 1. Lenz’s Law (fight the flux change) 2. Faraday’s Law (changing magnetic fields are the source of.

Published byMaude Price Modified over 8 years ago

Similar presentations

Presentation on theme: "Wed. Feb. 25 – Physics Lecture #32 Faraday’s Law II 1. Lenz’s Law (fight the flux change) 2. Faraday’s Law (changing magnetic fields are the source of."— Presentation transcript:

1 Wed. Feb. 25 – Physics Lecture #32 Faraday’s Law II 1. Lenz’s Law (fight the flux change) 2. Faraday’s Law (changing magnetic fields are the source of an electric field) Office Hours: Rachel Wed: noon to 1 or 1 – 2 Krishna Wed 1 – 3:30 (appointment), Thu: 3 – 4 (open) Seth as usual Wed. Mar. 4 All-Campus Mentoring Day (1 – 4) http://www.evergreen.edu/events/mentoringdays/ http://www.evergreen.edu/events/mentoringdays/ Academic Fair (4 – 6)

2 Example: Applying Lenz’s Law – Fight the Flux Change! A solenoid is used to create a uniform magnetic field that points into the page. A wire loop of area A is in the magnetic field, as shown. For each of the following cases, choose one of the following for the direction of the induced current in the loop: 1. Clockwise 2. Counterclockwise 3. No induced current 4. Not enough info x x x x x a)The loop is moved to the left, staying in the B field. b) The loop is crushed to smaller area. c)The magnetic field is increased. d)The magnetic field direction is reversed.

3 Applying Faraday’s Law for Changing Magnetic Field A uniform magnetic field B is produced in a solenoid of radius a, as shown. A loop is concentric with the axis of the solenoid, and has radius b. The current in the solenoid varies with time, so the magnetic field in the solenoid also varies with time, such that B ( t ) = B 0 t, where is a B 0 constant. a) What is the magnitude of the induced  in the loop? b) What is the source of this  ind ? c) What is the magnitude and direction of the induced electric field? d) What is different if b < a ? e) If the loop were conducting, what direction would the induced current flow? b a

4 A conducting wire with resistance R shaped into an isosceles right triangle (base b, height h ) enters a region of uniform magnetic field, as shown ( B inside box, 0 outside box), moved at constant velocity v. What is the direction of the current induced in the triangle as it enters the magnetic field? What is the magnitude of the current induced in the triangle as it enters the magnetic field? Challenge version (do on your own time): What if the wire were shaped as a circle of radius a ? v b h

5 Faraday Generator Paradox? A uniform magnetic field B points into the page as shown. A disk (radius a ) made out of a conducting material that lies in the plane of the page is rotated clockwise at constant . a) What can you say about the flux through the conducting disk? b) What can you say about the change in flux through the disk? c) What can you say about the  induced in the disk? x x x x x

6 A bar magnet is released above a circular loop of wire as shown, and falls through the loop. The loop is held fixed. Consider the following directions, as viewed when looking at the loop from above: 1. Clockwise3. No current 2. Counterclockwise4. Not enough information NSNS NSNS N What is the direction of any induced current in the wire loop, while the bar magnet is falling towards the loop from above? What is the direction of any induced current in the wire loop, while the bar magnet is falling away from the loop from below? N

7 Find the velocity of the bar as a function of time.

8

Download ppt "Wed. Feb. 25 – Physics Lecture #32 Faraday’s Law II 1. Lenz’s Law (fight the flux change) 2. Faraday’s Law (changing magnetic fields are the source of."

Similar presentations

Electromagnetic Induction

Electromagnetic Induction
A rectangular loop is placed in a uniform

A rectangular loop is placed in a uniform
F=BqvsinQ for a moving charge F=BIlsinQ for a current

F=BqvsinQ for a moving charge F=BIlsinQ for a current
Lecture 35: MON 17 NOV CH32: Maxwell’s Equations I

Lecture 35: MON 17 NOV CH32: Maxwell’s Equations I
© 2012 Pearson Education, Inc. { Chapter 29 Electromagnetic Induction (cont.)

© 2012 Pearson Education, Inc. { Chapter 29 Electromagnetic Induction (cont.)
Q29.1 A circular loop of wire is in a region of spatially uniform magnetic field. The magnetic field is directed into the plane of the figure. If the magnetic.

Q29.1 A circular loop of wire is in a region of spatially uniform magnetic field. The magnetic field is directed into the plane of the figure. If the magnetic.
Chapter 31 Faraday’s Law 31.1 Faraday’s Law of Induction

Chapter 31 Faraday’s Law 31.1 Faraday’s Law of Induction
Lecture 24 Faraday’s Law April 1. Electromagnetic Induction Slide 25-8.

Lecture 24 Faraday’s Law April 1. Electromagnetic Induction Slide 25-8.
ConcepTest 23.2a Moving Bar Magnet I

ConcepTest 23.2a Moving Bar Magnet I
Electromagnetism Quiz Review Mr. Davis Baltimore Poly.

Electromagnetism Quiz Review Mr. Davis Baltimore Poly.
Magnetic Fields Faraday’s Law

Magnetic Fields Faraday’s Law
Lecture 37: WED 22 APR CH32: Maxwell’s Equations I James Clerk Maxwell (1831-1879) Physics 2113 Jonathan Dowling.

Lecture 37: WED 22 APR CH32: Maxwell’s Equations I James Clerk Maxwell ( ) Physics 2113 Jonathan Dowling.
Biot-Savart Law The Field Produced by a Straight Wire.

Biot-Savart Law The Field Produced by a Straight Wire.
Induced EMF and Inductance 1830s Michael Faraday Joseph Henry M is mutual inductance.

Induced EMF and Inductance 1830s Michael Faraday Joseph Henry M is mutual inductance.
ConcepTest #21: A particle has a net positive charge, but it experiences no net electric force. Which of the following statements must be true? Hold up.

ConcepTest #21: A particle has a net positive charge, but it experiences no net electric force. Which of the following statements must be true? Hold up.
Dr. Jie ZouPHY 13611 Chapter 31 Faraday’s Law. Dr. Jie ZouPHY 13612 Outline Faraday’s law of induction Some observations and Faraday’s experiment Faraday’s.

Dr. Jie ZouPHY Chapter 31 Faraday’s Law. Dr. Jie ZouPHY Outline Faraday’s law of induction Some observations and Faraday’s experiment Faraday’s.
1. Up4. Left 2. Down5. Into the page 3. Right6. Out of the page (back of card) No Direction ConcepTest #17: A uniform magnetic field B points into the.

1. Up4. Left 2. Down5. Into the page 3. Right6. Out of the page (back of card) No Direction ConcepTest #17: A uniform magnetic field B points into the.
46 49 52 55 58 61 64 67 70 73 76 79 82 85 88 91 94 97 100 EXAM 1 Distribution Mean = 75.0 Standard deviation = 11.7.

EXAM 1 Distribution Mean = 75.0 Standard deviation = 11.7.
Selected Problems from Chapters 29 & 30. I 5I rd-r.

Selected Problems from Chapters 29 & 30. I 5I rd-r.
Physics 1502: Lecture 18 Today’s Agenda Announcements: –Midterm 1 distributed available Homework 05 due FridayHomework 05 due Friday Magnetism.

Physics 1502: Lecture 18 Today’s Agenda Announcements: –Midterm 1 distributed available Homework 05 due FridayHomework 05 due Friday Magnetism.

Similar presentations

Ads by Google