Take out a piece of paper

1. Take out a piece of paper • Jot down what you know about magnets… • Where do we find magnets? • What metals are magnetic? • How can you make or destroy magnets? • How do we use magnets? • And…what would life be like without them?

2. Magnets • Why do we discuss magnets along with electricity?

3. MAGnetIC Fields Why are we attracted to magnets? Or… Animal Magnetism: Myth or Misunderstanding

4. Discovery of Magnets • Some debate – one of the great controversies of our time! • Story of sheep herder in Magnesia region of Greece. • Or did the Chinese discover it thousands of years prior?

5. Magnetic Fields – Overhead • Look at magnets on overhead with iron filings • Magnetic flux lines – flow out of the north poles of magnets and into the south poles. • Closed loops • No overlap between 2 magnetic fields • Remind you of anything?

6. Magnetic Fields – Overhead • Paper clips • Soft vs hard • How do you destroy a magnet? • Can you see the magnetic fields? • Magnetic Domains

7. Magnets interact with electricity • Ampere’s – the guy that current is named for… • Studied magnetism and electricity • Observed current through a wire • In a magnetic field • Bounces or jumps

8. Current makes magnets? • Current causes a magnetic field around the wire • Ampere: interaction between 2 magnetic fields • One from a magnet • One from electricity • Electricity can create an electromagnet • Like at the junk yard or

9. Magnetic Fields – now that we’ve seen them… • The conventional way to think about magnetic fields… • Direction of concentric field lines based on RHR • Grab the wire with your right hand • The current flow lines up with your thumb • Your fingers curve in the direction of the magnetic fields.

10. Magnetic field around a coil • Take one loop of wire • Trace your right hand around the loop and look where your fingertips go • Resulting magnetic force inside the loop combines in one direction • What happens when you have 2 loops?

11. Magnetic fields – odds and ends • Magnetic Fields • Strength of the magnetic field • B (vector) • Into or out of page (x or .) • Arrows

12. What next? • Start Video?

13. Magnetic Force March 30/31, 2010

14. POTD • Check homework • Go over questions • Magnetic Force Lecture • Lab

15. repel, attract, attract two a, b parallel to the earth’s surface pointing towards the geographic north pole Hard Concentric circles Smaller region inside Opposite spin – magnetic fields cancel HW

16. Last time’s Lab • Please turn it in now! ; )

17. What’s the point? • Last time: • Magnetism from Electricity • We can see what happens! • Must be a force acting on it… • Today • Calculate the FORCE on a charge in a magnetic field

18. Magnetic Force • Consider a charged particle • Like an electron or a proton… • In the presence of a magnetic field • The force felt by the charge • F = qvB • q= charge (Coulombs) • V = velocity (m/s) • B = strength of magnetic field (Tesla)

19. Strength of B • The strength of a typical lab magnet • 1.5 T • The strength of the earth’s magnetic field • Is it stronger or weaker than a lab magnet? • Yes!! Nice call!! • Earth’s is about 50 μT • Or… 5.0 x 10-5 T

20. Force as in VECTOR • What direction is the force? • Assume B is a uniform magnetic field • The particle moves at a velocity of v • Right hand rule #2 • Force comes out of wall at you

21. Force as in VECTOR • Right hand rule #2 • Based on a positive charge • If it’s negative… • It’s the other direction

22. Example • A charged particle • Charge = 1.7 x 10-6 C • Is traveling north at 47 m/s • Through a uniform magnetic field • B = 1.5 T straight up • What is F? • F = qvB = (1.7 x 10-6 C) x (47 m/s) x 1.5 T • F = 1.2 x 10-4 N (east)

23. Uniform Magnetic Field • B is directed into the wall • A particle travels perpendicular to B • The force on the particle moves it • Perpendicular to travel direction • What is the path of the particle?

24. Is the particle + or - ?

25. Wire in a Uniform Magnetic Field • Similar to a charge…except… • Thumb along current’s path • Fingers up magnetic field • RHR

26. The calculation… • Force = qvB • qv = i x length • Force = Bil • B – magnetic field strength • i – current • l – length of wire in field

27. Example • A 6.0 m wire carries a current of 7.0 A in the x direction. • A magnetic force = 7.0 x 10-6 N in the –y direction • What is the direction and magnitude of the magnetic field? • 7.0 x 10-6 N = B x 7.0 A x 6.0 m • B = F/(i l) • B = 1.7 x 10-7 T

28. Can you see it? • What happens when you have 2 wires carrying current in the same direction. • Check your answer with a friend… • What about if they are in the opposite direction? • Same thing…

29. Think about a loop… • In a magnetic field…

30. Lab intro • Discovery lab • A magnet • A solenoid • A galvanometer • To measure current (μA) • Determine as much as you can • Your grade will be based on your discoveries • Don’t skimp

31. Induced Current March 31 & April 1, 2010

32. Lab Get homework out 0.081 T Up 0.75 N Attracts Out of page Turn in …

33. Today’s Learning Goals • What are the factors that affect induced current? • Understand that induced current generates its own magnetic field • Calculate the magnitude of an induced voltage

34. Right hand rules • What are they? • Check your understanding with a neighbor

35. Induced current • Relative motion between a wire and a magnetic field… • Creates a potential difference in the wire • Current flows – if the circuit is complete! • Recall: a charged particle moving in a magnetic field experience a force. • F = qvB

36. F = Bil: Consider a wire • Relative motion is required • due to the force • Pull it through a magnetic field • Perpendicular to the field • The magnetic force causes the positive ones to move • According to the RHR • And the negative charges to move • According to the “left” hand rule

37. F = qvB: Consider a wire • Separation of charges • Like a potential difference or voltage • If there is a completed circuit • Then current flows

38. Motion is essential • The voltage (and current) is maintained • As long as the wire is moving relative to the magnetic field. • The faster it moves – the greater the current • The greater the magnetic field, the greater the current

39. Orientation matters • In a complete circuit/loop of wire • more current flows if motion is perpendicular to the magnetic field. • The number of field lines that you “cut” as it moves… • Increase that and you increase current! • This means you can also rotate the coil in a magnetic field.

40. Faraday’s Law of Induction • Factors that affect the induced voltage: • The number of coils in the circuit (N) • The angle between B and the coil (θ) • Area of the coil (m2) • B = magnetic field strength (T) • emf = -N Δ(AB(cos θ))/ Δt

41. Faraday’s Law of Induction • emf = -N Δ(AB(cos θ))/ Δt • If you vary the: • cross sectional area • Magnetic field • The angle of orientation • With respect to a change in time • THEN you will see an induced emf

42. Example • A coil with 25 turns of wire • Cross sectional area of 1.8 m2 • Magnetic field applied at a right angle to the plane of the coil • The field is increased from 0.00 T to 0.55 T in 0.85 seconds • What is the magnitude of the induced emf?

43. The answer, please: • emf = -N Δ(AB(cos θ))/ Δt • emf = - 25 (1.8m2)cos0 (ΔB/Δt) • emf = - 45 (0.55 – 0.00T/0.85 s) • emf = - 29 V • Note that all factors are included in the answer. • But something has to change!

44. Lenz’s Law • If you induce a current in a wire • That current creates a magnetic field of its own! • Lenz tells us that the induced current creates a magnetic field that opposes the applied magnetic field. • The induced current tries to keep the field strength constant.

45. Today’s Goals • Factors that affect induced voltage/current • Induced current generates its own _________________? • Calculate the magnitude of an induced voltage

46. Lab! • Today’s lab DOES NOT connect directly with the lesson!! • It does relate to magnetic fields generated by current carrying wire… • Have fun!

47. Transformers April 5/8, 2010

48. Transformers: Saving the Planet • We generate electricity at Bonneville • Alternating current • We use it in our homes • 40 miles away • Is that a problem? • Line losses… • Big “i”… big losses… • So how do we change the current??

49. How indeed… • Remember the door bell example… • The bell only works when there is a change in electrical current. • The system is DC • When connected, a constant current flows. • What would happen if it was AC?

50. Same idea… • 2 coils connected with a soft metal core • The current in the first coil creates a magnetic field. • AC circuit - current changes • 60 times a second (Hertz) • The changing magnetic field induces a current in the secondary coil