Physics 212 Lecture 17, Slide 1 Physics 212 Lecture 17 Faraday’s Law.

Slides:

Advertisements

Similar presentations

Electromagnetic Induction

Advertisements

Chapter 30. Induction and Inductance

Physics 1304: Lecture 13, Pg 1 Faraday’s Law and Lenz’s Law ~ B(t) i.

Lecture 24 Faraday’s Law April 1. Electromagnetic Induction Slide 25-8.

Physics 4 Magnetic Induction Prepared by Vince Zaccone For Campus Learning Assistance Services at UCSB.

Magnetic Induction (Mutual Induction) The process by which a body having electric or magnetic properties produces magnetism, an electric charge, or an.

Halliday/Resnick/Walker Fundamentals of Physics 8th edition

Lenz’s Law AP Physics C Montwood High School R. Casao.

Chapter 22 Electromagnetic Induction Induced Emf and Induced Current There are a number of ways a magnetic field can be used to generate an electric.

Lecture 20 Discussion. [1] A rectangular coil of 150 loops forms a closed circuit with a resistance of 5 and measures 0.2 m wide by 0.1 m deep, as shown.

Electricity and Magnetism Electromagnetic Induction Mr D. Patterson.

Physics 24-Winter 2003-L181 Electromagnetic Induction Basic Concepts Faraday’s Law (changing magnetic flux induces emf) Lenz’s Law (direction of induced.

Two questions: (1) How to find the force, F on the electric charge, Q excreted by the field E and/or B? (2) How fields E and/or B can be created? Gauss’s.

Physics 1502: Lecture 19 Today’s Agenda Announcements: –Midterm 1 available Homework 06 next FridayHomework 06 next Friday Induction.

Biot-Savart Law The Field Produced by a Straight Wire.

1 Faraday’s Law of Induction If C is a stationary closed curve and S is a surface spanning C then The changing magnetic flux through S induces a non-electrostatic.

Physics 121: Electricity & Magnetism – Lecture 11 Induction I Dale E. Gary Wenda Cao NJIT Physics Department.

Electromagnetic Induction Objective: TSW understand and apply the concept of magnetic flux in order to explain how induced emfs are created and calculate.

When a coil of wire and a bar magnet are moved in relation to each other, an electric current is produced. This current is produced because the strength.

Book Reference : Pages To understand the direction of induced currents and their associated fields 2.To introduce the terms magnetic flux and.

Today’s Concept: Faraday’s Law Lenz’s Law

General electric flux definition

Physics 2112 Unit 16 Concept: Motional EMF.

Induction: Faraday’s Law

Chapter 31 Faraday’s Law.

© Shannon W. Helzer. All Rights Reserved. 1 Chapter 30 – Induction and Inductance.

An RL circuit in which L = 0

1 W09D2: Faraday’s Law: The Best Law in the Entire Universe Today’s Reading Assignment Course Notes: Sections

Chapter 20 Induced Voltages and Inductance. Faraday’s Experiment – Set Up A current can be produced by a changing magnetic field First shown in an experiment.

Lecture 9 Electromagnetic Induction Chapter 20.1  20.4 Outline Induced Emf Magnetic Flux Faraday’s Law of Induction.

Copyright © 2007 Pearson Education, Inc., publishing as Pearson Addison-Wesley PowerPoint ® Lecture prepared by Richard Wolfson Slide Electromagnetic.

Chapter 21 Magnetic Induction. Electric and magnetic forces both act only on particles carrying an electric charge Moving electric charges create a magnetic.

Fall 2008Physics 231Lecture 9-1 Electromagnetic Induction.

When the switch is closed, the current does not immediately reach its maximum value Faraday’s law can be used to describe the effect As the source current.

Electromagnetic Induction and Faradays Law Ripon High School AP Physics

Induced Voltages and Inductance

Faraday’s Law.

Magnetism #2 Induced EMF Ch.20. Faraday’s Law of Induction We now know that a current carrying wire will produce its own magnetic field with the lines.

Physics 102: Lecture 10, Slide 1 Faraday’s Law Physics 102: Lecture 10 Changing Magnetic Fields create Electric Fields Last Two Lectures Magnetic fields.

Induction - Faraday’s Law Sections Physics 1161: Lecture 12 Changing Magnetic Fields create Electric Fields.

Physics 212 Lecture 9, Slide 1 Physics 212 Lecture 9 Today's Concept: Electric Current Ohm’s Law & resistors Resistors in circuits Power in circuits.

Mon. Feb. 23 – Physics Lecture #31 Magnetic Induction & Faraday’s Law I 1. Motional emf (conductor moving through magnetic field induces electric field)

Copyright © 2009 Pearson Education, Inc. Chapter 29 Electromagnetic Induction and Faraday’s Law.

Devil physics The baddest class on campus IB Physics

1 Magnetic flux [weber Wb], defines the amount of magnetic field (B [Tesla]) which travels perpendicular to an area A [m 2 ] Symbol: Ф Unit: Weber Wb A.

Chapter 22 Electromagnetic Induction Induced Emf and Induced Current There are a number of ways a magnetic field can be used to generate an electric.

1 15. Magnetic field Historical observations indicated that certain materials attract small pieces of iron. In 1820 H. Oersted discovered that a compass.

Right-hand Rule 2 gives direction of Force on a moving positive charge Right-Hand Rule Right-hand Rule 1 gives direction of Magnetic Field due to current.

ElectroMagnetic Induction. What is E/M Induction? Electromagnetic Induction is the process of using magnetic fields to produce voltage, and in a complete.

PHY 102: Lecture Induced EMF, Induced Current 7.2 Motional EMF

1© Manhattan Press (H.K.) Ltd E.m.f. induced in a coil in a changing magnetic field E.m.f. induced in coil Magnetic flux (  ) Laws of Electromagnetic.

Magnetic Induction 1Physics is Life. Objectives To learn how magnetic fields can produce currents in conductors To understand how this effect is applied.

Problem 4 A metal wire of mass m can slide without friction on two parallel, horizontal, conducting rails. The rails are connected by a generator which.

Finally! Flux! Electromagnetic Induction. Objectives.

Physics 212 Lecture 17, Slide 1 Physics 212 Lecture 17 Faraday’s Law.

5/20/16 Oregon State University PH 213, Class #241 Changing Magnetic Flux: Faraday’s Law Mathematically, we can express the motion-induced voltage in a.

Problem 3 An infinitely long wire has 5 amps flowing in it. A rectangular loop of wire, oriented as shown in the plane of the paper, has 4 amps in it.

Physics 212 Lecture 17 Faraday’s Law.

EMF Induced in a Moving Conductor (“Motional EMF”)

Electromagnetic Induction

Direction of Induction

General Review Electrostatics Magnetostatics Electrodynamics

I2 is decreasing in magnitude I2 is constant

Electromagnetic Induction

Electricity and Magnetism

Electricity and Magnetism

Induction An induced current is produced by a changing magnetic field There is an induced emf associated with the induced current A current can be produced.

Electromagnetic Induction

Electricity and Magnetism

Chapter 31 Faraday’s Law 31.1 Faraday’s Law of Induction

Presentation transcript:

Physics 212 Lecture 17, Slide 1 Physics 212 Lecture 17 Faraday’s Law

Main Point 1 First, we introduced the concept of the magnetic flux and found that the motional emfs produced in the three examples from the last prelecture could all be written simply as the time rate of change of the magnetic flux through the circuit. Physics 212 Lecture 17, Slide 2

Main Point 2 Second, we introduced Faraday’s Law, which states that whenever magnetic flux changes in time, not just in the case of a moving conductor, an emf will be produced. In particular, this induced emf will just be equal to minus the time rate of change of the magnetic flux. Physics 212 Lecture 17, Slide 3

Main Point 3 Finally, we observed that this induced emf is determined by integrating the electric field around the loop, so that Faraday’s law can be written more generally only in terms of the electric and magnetic fields. A changing magnetic flux creates an electric field. Faraday’s law represents the first important step in establishing the deep connections between electric and magnetic fields which ultimately will explain the existence of electromagnetic waves and the identification of light as an electromagnetic phenomenon. Physics 212 Lecture 17, Slide 4

Physics 212 Lecture 17, Slide 5 Faraday’s Law Looks scary but it’s not – its amazing and beautiful ! A changing magnetic flux produces an electric field. Electricity and magnetism are on intimate terms

Physics 212 Lecture 17, Slide 6 In Practical Words: 1) When the flux  B through a loop changes, an emf is induced in the loop. There are many ways to change this… Faraday’s Law: where B A Think of  B as the number of field lines passing through the surface Flux Show Projection

Physics 212 Lecture 17, Slide 7

Physics 212 Lecture 17, Slide 8 Faraday’s Law In Words: 1) When the flux  B through a loop changes, an emf is induced in the loop. 2) The emf will make a current flow if it can (like a battery). 3) The current that flows induces a new magnetic field. 4) The new magnetic field opposes the change in the original magnetic field. B dB/dt

Physics 212 Lecture 17, Slide 9 The Ways Flux Can Change Change Area Change magnetic field Change orientation ALL THESE CHANGES CAN BE UNDERSTOOD FROM MOTIONAL EMF WHAT’S NEW WITH FARADAY? Flux can change WITHOUT moving any conductor !! e.g., change current that produces magnetic field e.g., change current that produces magnetic field

Physics 212 Lecture 17, Slide 10 Faraday’s Law Executive Summary: emf → current → field a) induced only when flux is changing b) opposes the change b) opposes the change

Physics 212 Lecture 17, Slide 11

Checkpoint 1a Physics 212 Lecture 17, Slide 12 A copper loop is placed in a uniform magnetic field as shown. You are looking from the right. Suppose the loop is moving to the right. The current induced in the loop is: A. zeroB. clockwiseC. counterclockwise

Physics 212 Lecture 17, Slide 13 Checkpoint 1b A copper loop is placed in a uniform magnetic field as shown. You are looking from the right. Now suppose the that loop is stationary and that the magnetic field is decreasing in time. The current induced in the loop is: A. zero B. clockwiseC. counterclockwise

Physics 212 Lecture 17, Slide 14 Checkpoint 1c Now suppose that the loop is spun around a vertical axis as shown, and that it makes one complete revolution every second. The current induced in the loop: A. Is zero B. Changes direction once per second C. Changes direction twice per second

Physics 212 Lecture 17, Slide 15 (copper is not ferromagnetic) X O B B Checkpoint 2 A horizontal copper ring is dropped from rest directly above the north pole of a permanent magnet Will the acceleration a of the falling ring in the presence of the magnet be any different than it would have been under the influence of just gravity (i.e. g)? A. a > gB. a = gC. a < g

Physics 212 Lecture 17, Slide 16

Calculation Physics 212 Lecture 17, Slide 17 Conceptual Analysis Strategic Analysis y x v0v0 a b x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x B A rectangular loop (height = a, length = b, resistance = R, mass = m) coasts with a constant velocity v 0 in + x direction as shown. At t =0, the loop enters a region of constant magnetic field B directed in the –z direction. What is the direction and the magnitude of the force on the loop when half of it is in the field?

Physics 212 Lecture 17, Slide 18

Physics 212 Lecture 17, Slide 19

Physics 212 Lecture 17, Slide 20