1. It’s Electrifying!
E-Mag

2. Electric Potential
Electric Potential is measured in volts (V)
The total electric potential energy divide by the charge.

3. 1 volt is equal to 1 joule per coulomb.
Electric potential is commonly called voltage.
Most outlets in your house are 110-volts
Some use 220-volts

4. Electric Energy Storage
Capacitors are used to store energy.
Voltage between plates of a capacitor become equally but oppositely charged.

5. Potential Difference
The change in potential (voltage) between two ends of a conductor or between battery terminals.
The flow of charges will continue until there is no longer a potential difference.

6. Potential Difference
The change in energy between two points in a circuit divided by the amount of charge
V = ∆E/q

7. Bird on a Power Line SAFE: both feet are on the
same voltage line thus no
potential difference!
NOT SAFE: If one leg is on the ground or another wire and the other one is on the power line, then there is a potential difference between the bird’s two legs.

8. Electric Current (I) The flow of electric charges.
Measured in amperes (A) one amp. is equal to the flow of 1 C of charge every second

9. Current Direction VS. Electron Flow
For purely HISTORICAL reasons, current is conventionally described as going from positive to negative!
The opposite way from electron flow!
Current direction was decided as going from positive to negative well before anyone had any idea of electrons' existence, let alone their being negative!

10. Voltage Sources Generators and batteries provide sources of voltage.
Batteries can have either dry or wet cells

11. Generators Convert mechanical energy into electrical energy
ex: household generators or car alternators

12. Batteries Energy is released during a chemical reaction.
Dry cells (Duracell) have a paste electrolyte. Wet cells (car batteries) have a liquid electrolyte.

13. Electric circuits are all about energy, not charge
When a battery no longer works, it is out of energy.
Chemicals inside the battery undergo a reaction that produces energy.
This energy-producing reaction pumps the charge through the battery from low energy terminal to high energy terminal and establishes the electric potential difference across the external circuit.
When a battery no longer works, it is because the chemicals have been consumed to the point that the ability of the battery to move the charge between terminals has been severely diminished.

14. Video: Electricity & Batteries
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15. Simple Fruit Battery

16. Resistance
Opposition to the flow of electric charges. It is increased if length is increased or width of wire is decreased.
Measured in ohms ()

17. Electrical Resistance

18. Ohm's Law defines the relationships between (P) power, (E) voltage, (I) current, and (R) resistance.
One ohm is the resistance value through which one volt will maintain a current of one ampere.

19. Formula Voltage (V) is equal to Current (I) times Resistance (R)
V = I R
Ohm’s Law sim:

20. Electric Current
The flow of electrons

21. Electric Circuit
Complete conducting path through which charge can flow
For Current (I) to flow, it must include a charge pump and be closed

22. Fact or Fiction?
When you turn on a light switch, electrons move rapidly from the socket to the lamp to light the bulb.

23. Electron Drift
Charge moves abnormally slowly - on average, about 1 meter in an hour - through a circuit.

24. Direct Current (DC) Charges always flow in one direction. Ex: battery
electrons always flow from the neg. terminal to the pos. terminal
AC/DC simulations

25. Alternating Current (AC)
Current flows in one direction, and then in the other direction…back and forth. Most US circuits operate at a frequency of 60 Hz.

26. AC/DC

27. Electrical Relationships
Water in a Hose
DC in a Wire
Electrical Units
Pressure
Voltage (V)
Volts (V)
Rate of Flow
Current (I)
Amperes, Amps (A)
Friction
Resistance (R)
Ohms (Ω)

28. Electric Power
Rate at which electric energy is converted into another form such as mechanical, heat or light energy.

29. Calculating Power
Electric power (PE) is equal to current (I) times voltage (V)
measured in watts (W)
PE = I V

30. Energy Converted
Electricity used (energy converted) is equal to power (kW) times time (hours)
Eelectric = Pt

31. What causes electric shock in the human body- current or voltage?
Current passing through the body depends on the voltage applied and the electrical resistance of the body. (ranges from 100 Ω if soaked in salt water to about 500,000 Ω if the skin is very dry)

32. Effects of Current on the body
0.001 A – barely felt
0.005 A – painful
0.010 A – muscle spasm
0.015 A – loss of muscle control
0.1 A (100 mA) can be fatal if current goes through the heart