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Lecture 9 Magnetic Fields due to Currents Ch. 30

Lecture 9 Magnetic Fields due to Currents Ch. 30. Cartoon - Shows magnetic field around a long current carrying wire and a loop of wire Topics Magnetic field produced by a moving charge Magnetic fields produced by currents. Big Bite as an example.

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Lecture 9 Magnetic Fields due to Currents Ch. 30

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  1. Lecture 9 Magnetic Fields due to Currents Ch. 30 • Cartoon - Shows magnetic field around a long current carrying wire and a loop of wire • Topics • Magnetic field produced by a moving charge • Magnetic fields produced by currents. Big Bite as an example. • Using Biot-Savart Law to calculate magnetic fields produced by currents. • Examples: Field at center of loop of wire, at center of circular arc of wire, at center of segment of wire. • Amperes’ Law : Analogous to Gauss’s Law in electrostatics, Useful in symmetric cases. • Infinitely long straight wire of radius a. Find B outside and inside wire. • Solenoid and Toroid Find B field. • Forces between current carrying wires or parallel moving charges • Demos • Torque on a current loop (galvanometer) • Iron filings showing B fields around wires with currents. • Compass needle near current carrying wire • Big Bite as an example of using a magnet as a research tool. • Force between parallel wires carrying identical currents. • Polling

  2. How do you calculate the magnetic field from a moving charge or from a current flowing in a wire? What do the flux lines look like?

  3. Magnetic Fields due to Currents • So far we have used permanent magnets as our source of magnetic field. Historically this is how it started. • In early decades of the last century, it was learned that moving charges and electric currents produced magnetic fields. • How do you find the Magnetic field due to a moving point charge? • How do you find the Magnetic field due to a current? • Biot-Savart Law – direct integration • Ampere’s Law – uses symmetry • Examples and Demos

  4. Magnitude of B is proportional to q, , 1/r2 and sin θ • B is zero along the line of motion. • The direction of B is given by the RHR rotating into • Magnetic permeability Topic: Moving charges produce magnetic fields q θ r Determined from Experiment Demo Show magnetic lines by sprinkling iron filings around a wire carrying current

  5. 108 m/s 90o Example: A point charge q = 1 mC (1x10-3C) moves in the x direction with v = 108 m/s. It misses a mosquito by 1 mm. What is the B field experienced by the mosquito?

  6. Topic: A current produces a magnetic field Recall the E field of a charge distribution “Coulombs Law” Biot-Savart Law To find the field of a current distribution use: This Law is found from experiment

  7. i R P θ is a vector coming out of the paper The angle between dl and r is constant and equal to 90 degrees. R i Find B field at center of loop of wire lying in a plane with radius R and total current i flowing in it. Magnitude of B field at center of loop. Direction is out of paper.

  8. i Example Loop of wire of radius R = 5 cm and current i = 10 A. What is B at the center? Magnitude and direction Direction is out of the page.

  9. What is the B field at the center of a segment or circular arc of wire? i Total length of arc is S. where S is the arc length S = Rθ0 θ0 is in radians (not degrees) θ0 R P Why is the contribution to the B field at P equal to zero from the straight section of wire?

  10. Suppose you had the following loop. Find magnetic field at center of arc length What is the magnitude and direction of B at the origin?

  11. Current enclosed by the path Ampere’s Law is Next topic: Ampere’s Law Allows us to solve certain highly symmetric current problems for the magnetic field as Gauss’ Law did in electrostatics. This dl is along the Amperian loop not along the wire. dl is the same as ds below Examples

  12. i i r By symmetry Suppose i = 10 A R = 10 cm Example: Use Ampere’s Law to find B near a very long, straight wire. B is independent of position along the wire and only depends on the distance from the wire (symmetry).

  13. Rules for finding direction of B field from a current flowing in a wire

  14. Suppose the currents are in the opposite direction? What direction is ? Find the force due to the current element of the first wire and the magnetic field of the second wire. Integrate over the length of both wires. This will give the force between the two wires. Force between two current carrying wires (Given by Ampere’s Law) The force is directed towards the wire (wires are attracted).

  15. Example: What is the magnetic field inside the wire? Find themagnetic field inside a long, thick wire of radius a IC = current enclosed by the circle whose radius is r

  16. Solenoid n is the number of turns per meter

  17. d c B a b IC is the total current enclosed by the path n is the the number of loops of current per meter and h is the length of one side. First evaluate the right side of the integral , it’s easy Right side =

  18. d c B a b Evaluate left side of the integral : n = the number of loops or turns per meter

  19. a < r < b a b Toroid N is the total number of turns Tokamak Toroid at Princeton I = 73,000 Amps for 3 secs B = 5.2 T

  20. Magnetic dipole inverse cube law z . P Magnetic field lines for a bar magnet and a current loop are similar

  21. Chapter 29 Problem 5 In Figure 29-36, two circular arcs have radii a = 13.1 cm and b = 10.6 cm, subtend angle θ = 74.0°, carry current i = 0.388 A, and share the same center of curvature P. What is the magnitude and direction of the net magnetic field at P? (Take out of the page to be positive.)

  22. Chapter 29 Problem 41 A 180 turn solenoid having a length of 22 cm and a diameter of 10 cm carries a current of 0.39 A. Calculate the magnitude of the magnetic field B inside the solenoid.

  23. Chapter 29 Problem 49 A student makes a short electromagnet by winding 150 turns of wire around a wooden cylinder of diameter d = 7.0 cm. The coil is connected to a battery producing a current of 4.0 A in the wire. • What is the magnetic moment of this device? (b) At what axial distance z>> d will the magnetic field of this dipole have the magnitude 5.0 µT (approximately one-tenth that of Earth's magnetic field)?

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