General Physics (PHY 2140)

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General Physics (PHY 2140) Lecture 15 Electricity and Magnetism Magnetism Applications of magnetic forces Induced voltages and induction Magnetic flux and induced emf Faraday s law http://www.physics.wayne.edu/~apetrov/phy2140/ Chapter 19-20 1

Lightning Review Last lecture: 1. Magnetism Charged particle in a magnetic field Ampere s law and applications F = BIlsinθ τ = NBIAsinθ mv r = qb µ 0I B = 2π r Review Problem: A rectangular loop is placed in a uniform magnetic field with the plane of the loop parallel to the direction of the field. If a current is made to flow through the loop in the sense shown by the arrows, the field exerts on the loop: 1. a net force. 2. a net torque. 3. a net force and a net torque. 4. neither a net force nor a net torque. 2

19.10 Magnetic Field of a current loop Magnetic field produced by a wire can be enhanced by having the wire in a loop. x 1 B I x 2 3

19.11 Magnetic Field of a solenoid Solenoid magnet consists of a wire coil with multiple loops. It is often called an electromagnet. 4

Solenoid Magnet Field lines inside a solenoid magnet are parallel, uniformly spaced and close together. The field inside is uniform and strong. The field outside is non uniform and much weaker. One end of the solenoid acts as a north pole, the other as a south pole. For a long and tightly looped solenoid, the field inside has a value: v B = µ ni o 5

Solenoid Magnet B = µ ni o n = N/l : number of (loop) turns per unit length. I : current in the solenoid. µ π o 7 = 4 10 Tm/ A 6

Example: Magnetic Field inside a Solenoid. Consider a solenoid consisting of 100 turns of wire and length of 10.0 cm. Find the magnetic field inside when it carries a current of 0.500 A. N = 100 l = 0.100 m I = 0.500 A µ = π o 7 4 10 / Tm A N 100turns n= = = 1000 turns/ m l 0.10m o B= 6.28 10 ( 4 10 7 / )( 1000 / )( 0.500 ) B= µ ni= π Tm A turns m A 4 T 7

Comparison: Electric Field vs. Magnetic Field Electric Magnetic Source Charges Moving Charges Acts on Charges Moving Charges Force F = Eq F = q v B sin(θ) Direction Parallel E Perpendicular to v,b Field Lines Opposites Charges Attract Currents Repel 8

Chapter 20 Induced EMF and Induction 9

Introduction Previous chapter: electric currents produce magnetic fields (Oersted s( experiments) Is the opposite true: can magnetic fields create electric currents? 10

20.1 Induced EMF and magnetic flux Definition of Magnetic Flux Just like in the case of electric flux, consider a situation where the magnetic field is uniform in magnitude and direction. Place a loop in the B-field. B The flux, Φ,, is defined as the product of the field magnitude by the area crossed by the field lines. Φ= BA= BAcosθ B where is the component of B perpendicular to the loop, θ is the angle between B and the normal to the loop. Units: T mt 2 or Webers (Wb) The value of magnetic flux is proportional to the total number of magnetic field lines passing through the loop. 11

Problem: determining a flux A square loop 2.00m on a side is placed in a magnetic field of strength 0.300T. If the field makes an angle of 50.0 with the normal to the plane of the loop, determine the magnetic flux through the loop. 12

A square loop 2.00m on a side is placed in a magnetic field of strength 0.300T. If the field makes an angle of 50.0 with the normal to the plane of the loop, determine the magnetic flux through the loop. Solution: Given: L = 2.00 m B = 0.300 T θ = 50.0 Find: From what we are given, we use Φ= BAcosθ = ( 0.300T)( 2.00m) 2 cos 50.0 = 0.386 Tm 2 Φ=? 13

20.1 Induced EMF and magnetic flux Faraday s experiment Picture Molecular Expressions Two circuits are not connected: no current? However, closing the switch we see that the compass needle moves and then goes back to its previous position Nothing happens when the current in the primary coil is steady But same thing happens when the switch is opened,, except for the needle going in the opposite direction What is going on? 14

20.2 Faraday s law of induction Induced current I v S N 15

20.2 Faraday s law of induction I v B I S N B I v A current is set up in the circuit as long as there is relative motion between the magnet and the loop. 16

Does there have to be motion? (induced) I I - + AC Delco 1 volt 17

Does there have to be motion? I - + AC Delco 1 volt 18

Does there have to be motion? (induced) I - + AC Delco 1 volt 19

Does there have to be motion? NO!! AC Delco - + 1 volt 20

Maybe the B-field B needs to change.. B v 21

Maybe the B-field B needs to change.. I B v 22

Maybe the B-field B needs to change.. I I B v I 23

Faraday s law of magnetic induction In all of those experiment induced EMF is caused by a change in the number of field lines through a loop. In other words, The instantaneous EMF induced in a circuit equals the rate of change of magnetic flux through the circuit. Lenz s law E = Lenz s Law: The polarity of the induced emf is such that it produces a current whose magnetic field opposes the change in magnetic flux through the loop. That is, the induced current tends to maintain the original flux through the circuit. N Φ t The number of loops matters 24

Applications: Ground fault interrupter Electric guitar SIDS monitor Metal detector 25

Example : EMF in a loop A wire loop of radius 0.30m lies so that an external magnetic field of strength +0.30T is perpendicular to the loop. The field changes to -0.20T in 1.5s. (The plus and minus signs here refer to opposite directions through the loop.) Find the magnitude of the average induced emf in the loop during this time. B 26

A wire loop of radius 0.30m lies so that an external magnetic field of strength +0.30T is perpendicular to the loop. The field changes to -0.20T in 1.5s. (The plus and minus signs here refer to opposite directions through the t loop.) Find the magnitude of the average induced emf in the loop during this time. Given: r = 0.30 m B i = 0.30 T B f = -0.20 T t = 1.5 s Find: EMF=? The loop is always perpendicular to the field, so the normal to the loop is parallel to the field, so cosθ = 1. The flux is then Initially the flux is Φ = i Φ= BA= Bπ r ( ) ( ) 2 2 0.30T π 0.30m =0.085 T m and after the field changes the flux is f ( ) ( ) 2 2 0.20T π 0.30m =-0.057 T m Φ = 2 emf The magnitude of the average induced emf is: Φ Φ f Φi = = = = t t 1.5s 2 2 0.085 T m -0.057 T m 0.095 V 27

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