Currents and Magnetism

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Presentation transcript:

Currents and Magnetism Physics 1161: Lecture 13 Currents and Magnetism Textbook Sections 22-4 – 22-7 1

Force of B-field on Current Force on 1 moving charge: F = q v B sin(q) Out of the page (RHR) q v + Force on many moving charges: F = (q/t)(vt)B sin(q) = I L B sin(q) Out of the page! v L = vt B I = q/t +

Preflight 13.1 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. B I L  F=ILBsin A B C D I Here  = 0. What is the direction of the force on section A-B of the wire? force is zero out of the page into the page 45% 36% 18%

Preflight 13.2 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. Palm into page. v F B A B C D I X F What is the direction of the force on section B-C of the wire? force is zero out of the page into the page 9% 45% 45%

Torque on Current Loop in B field A B C D I X F • A B C D F Look from here The loop will spin in place! 86% got that the net force was zero; 45% said it wouldn’t move -- Could be confusion about move vs spin Preflights 13.3, 13.4 Net force on loop is zero. But the net torque is not! 91%

Torque on Current Loop in B field W L A B C D I X F • A B C D F f Force on sections B-C and A-D: F = Torque on loop is t = 2 x (L/2) F sin(f) = (length x width = area) LW = A !  Torque is t =

Torque on Current Loop in B field W L A B C D I X F • A B C D F f L/2 L/2 Force on sections B-C and A-D: F = IBW Torque on loop is t = 2 x (L/2) F sin(f) = ILWB sin(f) (length x width = area) LW = A !  Torque is t = I A B sin(f)

Torque on Current Loop N t = I A B sinf Direction: normal Magnitude: f between normal and B Direction: Torque tries to line up the normal with B! (when normal lines up with B, f=0, so t=0! ) Even if the loop is not rectangular, as long as it is flat: t = I A B sinf. N (area of loop) # of loops

Compare the torque on loop 1 and 2 which have identical area, and current. t1 > t2 t1 = t2 t1 < t2

Compare the torque on loop 1 and 2 which have identical area, and current. t1 > t2 t1 = t2 t1 < t2 t = I A B sinf Area points out of page for both! f = 90 degrees

Currents Create B Fields Magnitude: Lines of B B Current I OUT • r r = distance from wire Right-Hand Rule-2 Thumb: along I Fingers: curl along B field lines

Right Hand Rule 2! Fingers give B! I wire

Preflight 13.6 A long straight wire is carrying current from left to right. Near the wire is a charge q with velocity v v I (a) r • (b) F same • B Compare magnetic force on q in (a) vs. (b) (a) has the larger force (b) has the larger force force is the same for (a) and (b) 27% 59% 14% θ is angle between v and B (θ = 90° in both cases)

x Left Right Up Down Zero 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 x Left Right Up Down Zero

x Left Right Up Down Zero 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”? B x x Left Right Up Down Zero

Force between current-carrying wires I towards us B • • Another I towards us F Conclusion: Currents in same direction attract! • I towards us B F  Another I away from us Conclusion: Currents in opposite direction repel! Note: this is different from the Coulomb force between like or unlike charges.

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(q) Direction Parallel E Perpendicular to v,B Field Lines Opposites Charges Attract Currents Repel

Magnetic Fields of Currents http://hyperphysics.phy-astr.gsu.edu/hbase/magnetic/magfie.html#c1

Right Hand Rule 3 Magnetic Field of Solenoid

B Field Inside Solenoids Magnitude of Field anywhere inside of solenoid : B=m0 n I n is the number of turns of wire/meter on solenoid. m0 = 4p x10-7 T m /A (Note: N is the total number of turns, n = N / L) Right-Hand Rule for loop/solenoid Fingers – curl around coil in direction of conventional (+) current Thumb - points in direction of B along axis Magnetic field lines look like bar magnet! Solenoid has N and S poles!

Preflight 13.8 Right Hand Rule! What is the direction of the magnetic field produced by these solenoids? to the Right to the Left 76% 24% Right Hand Rule!

What is the net force between the two solenoids? Attractive Zero Repulsive

What is the net force between the two solenoids? Attractive Zero Repulsive Look at field lines, opposites attract. Look at currents, same direction attract.