1. Chapter 36: Magnetism
Purpose: To describe magnetic field around a permanent magnet.
Objectives:
Describe a magnetic poles
Describe magnetic field.
Magnetic field lines.

2. Warm-up Where and how do we use magnets?
What is an electro magnet and where is it used?

3. Describing a magnet
magnet is a material or object that produces a magnetic field.
A bar magnet
Horse shoe magnet

4. Magnetic poles
Magnetic poles are regions that produce magnetic forces s N
North pole
South pole

5. Like poles repel, unlike poles attract.
South repels south, North Repels North, and South attracts North.

6. Breaking the magnet Magnetic poles cannot be isolated.
When you break a magnet into two you end up with two magnets.
Keep breaking further and further, you still get the same results.

7. Magnetic field
The magnetic field (usually denoted B) is a space around a magnet where magnetic force is exerted.
The SI units of magnetic field (B) is Tesla (T)
Iron fillings trace out a pattern of magnetic field lines in the space around the magnet.

8. Magnetic field is represented by magnetic field lines
where lines are closer together, the field strength is greater.
The direction of magnetic field is, from North pole to south pole.

9. Nature of magnetic field
What is in a magnet that makes it a magnet?
Permanent magnets, like all other substances are composed of atoms that contain electrons. These electrons are in a continuous motion.
Electrons have two types of motion;
a) spinning on their positions and
b) Orbiting around the nucleus.
Magnetic Materials

10. source of all magnetism
The source of all magnetism is moving electric charge (motion of electrons)
Every spinning and orbiting electron is a tiny magnet that creates a magnetic field around an atom.
Question;
What is the source of magnetic field on a bar magnet?_____________________________

11. Magnetic domains Magnetic domains are large cluster of aligned atom.
Each domain contains dipoles (magnetized atoms) that are aligned.
Irregular shaped domains with aligned dipoles

12. Magnetic and non magnetic
Magnetic materials have electrons spinning in the same direction. This leads to aligned atoms with a strong magnetic field around them.
Examples include Iron, Nickel, and Cobalt
For non magnets, the electron spins opposite to one another causing their magnetic fields to cancel each other. Therefore, no net magnetic field exists

13. Class work
Using double bubble Differentiate between magnetic poles from electric charges.
Textbook Pg 575 # 1 -5

14. EARTHS MAGNETIC FIELD
Earth’s magnetic fields are due to large currents created by movement of molten matter at the earth’s core. (The molten matter is made of mostly Iron and nickel)

15. Electron Vs Earth

16. Importance of earths magnetic field
The Earth's surface and its inhabitants are protected from dangerous cosmic radiation (energetic protons) from the Sun by the Earth's magnetic field.
Venus doesn’t have a magnetic field.

17. Magnetic declination
Magnetic declination is the discrepancy between the orientation of a compass and true North.
That means that compasses do not point to true Geographic North.
Magnetic declination
The discrepancy is about
The earth’s polarity changes every

18. Beam of electrons
Since moving electrons create magnetism, a beam of electrons will have a magnetic field around it.

19. Electric currents and Magnetic fields
Straight conductors (wires) will have magnetic fields around them. The magnetic field form complete loops around the conductors.

20. Direction of magnetic field
Second Right hand rule
The thumb indicate the direction of current.
The four fingers indicate direction of magnetic field.

21. Right hand rule
Right hand rule
Electric current
Magnetic field

22. Question
Consider a beam of electrons moving from west to east, what is the direction of magnetic field at point G? N E W e-
G • S

23. Question
What is the direction of a magnetic field at the center of a current carrying loop with a counter-clockwise flow of current?

24. answer
Out of the page

25. Magnetic Field Produced by a Coil
This is how magnetic field lines looks like in and out of an electromagnet
Counter-clockwise current----North pole
Clockwise current flow---South Pole.

26. North and south poles of an electromagnet.
Second Right hand rule.
Wrap the fingers around the coil in the direction of current.
The thump will indicate the North pole.

27. question
What is the direction of the magnetic field inside the coil shown on the right?

28. Class work
Textbook Pg 575 # 6-11, pg 576 # 21-25

29. Magnetic Force Purpose: Objectives:
The magnitude of a force on a moving charge (charged particle) is given by the formula
F = vqB
Objectives:
Magnetic field formula
The magnetic force formula
Workbook exercises

30. Magnetic force on moving charge
What happens when a charge/current moves near a magnetic field? B N
Magnetic field S A
Current carrying conductor

31. Direction of current and magnetic field
Maximum force is achieved when the current is flowing perpendicular to the magnetic field.
If the current is flowing parallel to the magnetic field, there will be no interaction and therefore no force

32. Direction of Force on a conductor
The conductor is forced to move in a certain direction.
The Third right hand rule indicates the direction of the force.
Concepts in Motion

33. What is the direction of the magnetic force on the current in each of the six cases below

34. Magnetic force Formula
Magnetic force formula is as shown;
F = Force
V= speed of charge
B= magnetic field strength.
When Current (I) and the length (L) of conductor is given we use the 2nd formula.

35. The magnetic field formula
Where;
B = magnetic field,
V = speed of the charged particle, and
q = charge of the particle,
F = force of the field

36. Example
A proton speeding at 3.0 x107 m/s experiences a magnetic field of 4.0 Teslas. What is the magnetic force pulling on the proton?

37. Class work
Textbook page 575, # 12-20, 26-28

38. Warm-up
What happens when you put a small compass in a magnetic field say of a straight conductor?

39. Warm-up How come a magnet can attract a nail?
What kind of charge, negative or positive, attracts a neutral object?
What happens to the electrons within a iron nail when it gets magnetized?

40. Lab
Lab- magnetic field

41. Warm-up:
Can a stationary electron be set into motion with a magnetic field? With an electric field? Explain.

42. Class work
Workbook problems
Pg 226; #s 1- 4 and
Pg 231; #s A1- A5

43. Putting electricity to work
This force can then be used for daily work such as;
sharpen pencils
Cut down trees,
Driving cars,
In other words, we transform electrical energy to mechanical energy in order to do work.

44. Simple Galvanometer
This is a meter that detects small electric currents.
When electricity is present in the coil, each loop produces its own effect on the needle causing it to deflect.

45. Electric motor
This is the device used to transform electrical energy to mechanical energy
Concepts in Motion

46. Direct Current Motors
Direct Current Motors

47. Research Homework Explain how a motor works
Explain how a speaker works