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Physics 102: Lecture 9, Slide 1 Currents and Magnetism Physics 102: Lecture 09.

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Presentation on theme: "Physics 102: Lecture 9, Slide 1 Currents and Magnetism Physics 102: Lecture 09."— Presentation transcript:

1 Physics 102: Lecture 9, Slide 1 Currents and Magnetism Physics 102: Lecture 09

2 Physics 102: Lecture 9, Slide 2 Summary of Today Last time: –Magnetic forces on moving charge magnitude F = qvBsin(  ) direction: right-hand-rule Today: –Magnetic forces on currents and current loops –Magnetic fields due to currents long straight wire solenoid

3 Physics 102: Lecture 9, Slide 3 Force of B-field on Current + v  Force on 1 moving charge: –F = q v B sin(  ) –Out of the page (RHR) Force on many moving charges: –F = q v B sin(  ) = (q/t) (vt) B sin(  ) = I L B sin(  ) –Out of the page! v L = vt B I = q/t ++++ B

4 Physics 102: Lecture 9, Slide 4 force is zero out of the page into the page B I L  F=IBLsin  Here  = 0 a b c d B I Preflight 9.1 A rectangular loop of wire is carrying current as shown. There is a uniform magnetic field parallel to the sides a-b and c-d. What is the direction of the force on section a-b of the wire?

5 Physics 102: Lecture 9, Slide 5 force is zero out of the page into the page a b c d B I Preflight 9.2 A rectangular loop of wire is carrying current as shown. There is a uniform magnetic field parallel to the sides a-b and c-d. What is the direction of the force on section b-c of the wire? F

6 Physics 102: Lecture 9, Slide 6 B I L  F=IBLsin  Here  = 180° a b c d B I Force on loop A rectangular loop of wire is carrying current as shown. There is a uniform magnetic field parallel to the sides a-b and c-d. Force on section c-d is zero! Same as a-b

7 Physics 102: Lecture 9, Slide 7 force is zero out of the page into the page a b c d B I ACT: Force on loop (cont’d) A rectangular loop of wire is carrying current as shown. There is a uniform magnetic field parallel to the sides a-b and c-d. What is the direction of the force on section d-a of the wire? F

8 Physics 102: Lecture 9, Slide 8 Net force on loop is zero. Look from here But the net torque is not! Torque on Current Loop in B field The loop will spin in place! Preflights 9.3, 9.4: a b c d B I F F a b c d F F B

9 Physics 102: Lecture 9, Slide 9 Torque on Current Loop The loop will spin in place! a b c d F F B a b c d F F B a b c d F F B Recall from Phys 101: B F F  Torque on loop is  = L F sin(  ) = I Lw B sin(  ) Force on sections b-c and a-d: F = IBw  Torque is: Lw = A ! L w

10 Physics 102: Lecture 9, Slide 10 x x x x x x x x ACT: Torque on Current Loop What is the torque on the loop below?  < IAB  = IAB  > IAB

11 Physics 102: Lecture 9, Slide 11 Torque on Current Loop It is useful to define normal vector ⊥ to loop a b c d F F B B F F  Torque is:  normal   = 180 –  If there are N loops: Note torque will align normal parallel to B like a magnetic dipole! Even if loop is not rectangular, as long as it is flat a b c d F F B  normal SN

12 Physics 102: Lecture 9, Slide 12 Current loops act like dipoles Orbits of electrons “spin” Electron orbit and “spin” are current loops Why some materials are magnetic Nuclear Magnetic Resonance (NMR) and MRI

13 Physics 102: Lecture 9, Slide 13 B Compare the torque on loop 1 and 2 which have identical area, and current. I ACT: Torque (1) B I (2) 1)  1 >  2 2)  1 =  2 3)  1 <  2 Area points out of page for both!  = 90  = I A B sin( 

14 Physics 102: Lecture 9, Slide 14 Currents create magnetic fields Straight wire carrying current I generates a field B at a distance r: Magnitude Direction “Right-hand rule 2”: –Thumb of right hand along I –Fingers of right hand along r –Out-of-palm points along B “Permeability of free space” (similar to  0 for electricity) Note: there are different versions of RHR I (out of page) B r B field circles wire

15 Physics 102: Lecture 9, Slide 15 A long straight wire is carrying current from left to right. Near the wire is a charge q with velocity v Compare magnitude of magnetic force on q in (a) vs. (b) a) has the larger force b) has the larger force c) force is the same for (a) and (b) v I v (a) r r (b) F F ACT/Preflight 9.6 qq

16 Physics 102: Lecture 9, Slide 16 Two long wires carry opposite current What is the direction of the magnetic field above, and midway between the two wires carrying current – at the point marked “X”? x ACT: Adding Magnetic Fields 1) Left 2) Right 3) Up 4) Down 5) Zero

17 Physics 102: Lecture 9, Slide 17 Force between current-carrying wires B Another I towards us F Currents in same direction attract! I towards us B Another I away from us F Currents in opposite direction repel! Currents in same directionCurrents opposite direction I towards us

18 Physics 102: Lecture 9, Slide 18 Comparison: Electric Field vs. Magnetic Field ElectricMagnetic Source ChargesMoving Charges Acts on Charges Moving Charges Force F = Eq F = q v B sin(  ) Direction Parallel EPerpendicular to v,B Field Lines + Opposites Charges AttractCurrents Repel

19 Physics 102: Lecture 9, Slide 19 What is the direction of the force on the top wire, due to the two below? 1) Left 2) Right 3) Up 4) Down 5) Zero ACT: Force between Wires

20 Physics 102: Lecture 9, Slide 20 B I B I B is uniform everywhere inside of solenoid: n is the number of turns of wire/meter (n = N/L) B field lines look like bar magnet! Solenoid has N and S poles! Solenoids Magnitude Direction Use “Right-hand rule 2” A solenoid consists of N loops of wire

21 Physics 102: Lecture 9, Slide 21 (1) Attractive (2) Zero (3) Repulsive ACT: The force between the two solenoids is …

22 Physics 102: Lecture 9, Slide 22 Summary of Right-Hand Rules B I B I r RHR 1RHR 2 Alternate Force on moving q B field from current I Straight wire Solenoid I

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