1. Electric Fields and Potential

2. Electric field – a force field that fills the space around every electric charge or charges
Example:
Electron
Proton

4. An electric field has both magnitude and direction
Therefore, an electric field can be represented using…
VECTORS!!!

5. Force Field Lines
The vectors are drawn by how they will affect a small positive test charge

6. The field of a positive charge near a negative charge

7. Two positive charges

8. Two negative charges

9. Electric Field = Force ÷ charge
So… the strength of the electric field, E, is given by
Electric Field = Force ÷ charge
E = F ÷ q

10. For example:
A 0.5 C charge experiences a force of 20 N when placed in an electric field.
What is the strength of the electric field, E?
E = F ÷ q =
20 N ÷ 0.5 C =
40 N/C

11. The electric field near a charged piece of plastic or styrofoam is around 1000 N/C.
The electric field in a television picture tube is around 10,000 N/C.
The electric field at the location of the electron in a Hydrogen atom is 500,000,000,000 N/C!
The further you go from an electric charge, the weaker the field becomes.

12. Electric Shielding
There is no way to shield from gravity, but there is a way to shield from an electric field….
Surround yourself or whatever you wish to shield with a conductor (even if it is more like a cage that a solid surface)
That’s why certain electric components are enclosed in metal boxes and even certain cables, like coaxial cables have a metal covering.
The covering shields them from all outside electrical activity.

13. “Faraday Cage”

14. Electric Shielding
Electrons repel toward the outside of any conducting surface
Net charge inside is zero
Electrons flow outward evenly, but pile up on sharp corners
Shielding is important in electronic devices such as televisions and computers

16. Voltage Electric potential is commonly called VOLTAGE.
Voltage = Energy / charge or you can rearrange to say Energy = Voltage x charge

17. Remember, one Coulomb is a HUGE amount of energy!
Energy = Voltage x charge
Let’s say you rub a balloon on your head and transfer 3000 V.
How much energy is that?
Energy = 3000 V x C
Energy = J
That’s not much energy! High Voltage does not necessarily mean that there’s a lot of useful energy or that something is dangerous.

18. Electric Field 3 meters DV = Ed
When you change the position of a charge in an electric field, the Electric Potential (Voltage), V, changes.
The change in Potential (“pressure”), called the “Potential Difference” is given by
DV = Ed
Electric Field
For example, the potential difference between two locations separated by 3 meters in a 4000 N/C electric field is given by
DV = Ed = 4000 N/C x 3 m =
12,000 V
3 meters

20. Van de Graaff generator:
Static devices
Electroscope: the separation of metal leaves indicates the presence of static charge
Van de Graaff generator:
charge is delivered by a rubber belt to a metal dome
Electrophorus a device used to transfer electric charge

21. Capacitor – a device used to store electrical energy

22. Capacitors are Used in camera flashes defibrillators
Computers: tiny capacitors store the 1’s and 0’s for the binary code
Many keyboards have a capacitor beneath each key that records every key stroke.
Virtually every electronic device

23. Vocabulary Capacitor Electric field Electric potential energy
Volt
voltage