1. Electric Current Creates a Magnetic Field

2. Electric Currents Also Create Magnetic Fields
The magnetic field lines form circles around the wire. The iron filings are less affected by the field as the distance from the wire increases, indicating that the field is getting weaker as the distance from the wire increases.

3. Electric Currents Also Create Magnetic Fields
A solenoid is a series of current loops placed along a common axis. The field outside is very weak compared to the field inside. Inside the solenoid, the magnetic field lines are reasonably evenly spaced; the field inside is nearly uniform.

4. The Magnetic Field of a Straight, Current-Carrying Wire
The iron filings line up in circles around a straight, current carrying wire.

5. The Magnetic Field of a Straight, Current-Carrying Wire

6. Right-Hand Rule for a Magnetic Field Created by a Convential Current

7. The Magnetic Field of a Straight, Current-Carrying Wire
Magnetism often requires a three- dimensional perspective.
To indicate field vectors or currents that are perpendicular to the page, we use

8. The Magnetic Field of a Straight, Current-Carrying Wire
Here is an example of the notation with compasses around a current that is directed into the page.

9. Question 1
A long, straight wire extends into and out of the screen. The current in the wire is
Into the screen.
Out of the screen.
There is no current in the wire.
Not enough info to tell the direction.
Answer: B

10. Question 1
A long, straight wire extends into and out of the screen. The current in the wire is
Into the screen.
Out of the screen.
There is no current in the wire.
Not enough info to tell the direction.
Right-hand rule

11. Question 2
Point P is 5 cm above the wire as you look straight down at it. In which direction is the magnetic field at P?
Answer: D

12. Question 2
Point P is 5 cm above the wire as you look straight down at it. In which direction is the magnetic field at P? D

13. Question 3
Compared to the magnetic field at point A, the magnetic field at point B is
Half as strong, same direction.
Half as strong, opposite direction.
One-quarter as strong, same direction.
One-quarter as strong, opposite direction.
Can’t compare without knowing I.
Answer: B

14. Question 3
Compared to the magnetic field at point A, the magnetic field at point B is
Half as strong, same direction.
Half as strong, opposite direction.
One-quarter as strong, same direction.
One-quarter as strong, opposite direction.
Can’t compare without knowing I.

15. The Magnetic Field of a Current Loop
Here we see three views of a current-carrying loop.

16. The Magnetic Field of a Current Loop

17. Question 4
The following diagram shows a current loop perpendicular to the page; the view is a “slice” through the loop. The direction of the current in the wire at the top and at the bottom is shown. What is the direction of the magnetic field at a point in the center of the loop?
To the left Up
To the right
Down
Answer: C

18. Question 4
The following diagram shows a current loop perpendicular to the page; the view is a “slice” through the loop. The direction of the current in the wire at the top and at the bottom is shown. What is the direction of the magnetic field at a point in the center of the loop?
To the left Up
To the right
Down

19. Question 5 Where is the north magnetic pole of this current loop?
Top side
Bottom side
Right side
Left side
Current loops don’t have north poles.
Answer: B

20. Question 5 Where is the north magnetic pole of this current loop?
Top side
Bottom side
Right side
Left side
Current loops don’t have north poles.