1. Current and Resistance
Chapter 31

2. Batteries

3. - + Battery Batteries provide Chemical Electricity
Electrons “bunch up” or have the potential to flow from the negative end
Electrons can’t flow in an isolated battery - + e e
Chemical Reaction that produces electrons
Chemical Reaction that absorbs electrons

4. Circuits

5. Drift Speed Electrons do not flow through wires like pipes
Electric field gives direction to the random motion of electrons. (vD = drift speed)

6. 0.05 mm/s
About 5 ½ hours to travel one meter (coin waterfall at Chuck-E-Cheese)
About a year to go 1 mile
Electron Current (ie)
ie = neAvD
ne = electron density

7. Calculate the electron current in a 2
Calculate the electron current in a 2.0 mm diamter copper wire if the electron drift speed is 1.0 X 10-4 m/s. (2.7 X 1019 s-1)

8. Conventional Current Flows positive to negative
Opposite of electron flow (electron current)

10. Current (I) Current – Net amount of charge per unit time
1 coulomb/second = 1Ampere
I = DQ Dt
I = dQ I = eie electron current dt

11. The electron current through a wire is 1.2 X 1019 electrons/s.
Calculate the current, I (1.9 A)
Calculate the amount of charge that flows each hour (6800 C)

12. Current Density (J)

13. A 1.0 A current passes through a 1.0 mm diameter wire.
Calculate the current density. (1.3 X 106 A/m2)
Calculate the drift speed of the electron. (0.13 mm/s)

14. A 5.0 A current passes through a 3.2 mm diameter wire.
Calculate the current density. (6.2 X 105 A/m2)
Calculate the drift speed of the electron. (0.05 mm/s)

15. Current: Ex. 1
A steady current of 2.5 A flows through a wire for 4.0 min. How much charge passed through any point in the circuit? I = DQ Dt DQ = IDt DQ = (2.5 A)(240 s) = 600 C

16. How many electrons would this be. 1 electron = 1
How many electrons would this be? 1 electron = 1.60 X C 600 C 1 electron = 3.8 X 1021electrons 1.60 X C

17. Current Density (J) Conductivity (s) Resistivitiy (r) Current density

19. A 2.0 mm diameter aluminum wire carries a current of 800 mA.
Calculate the current density using J = I/A (2.55 X 105 A/m2)
Calculate the electric field inside the wire ( V/m)

20. A copper wire has a diameter of 3.2 mm. The current is 5.0 A.
Calculate the current density of the wire (6.2 X 105 A/m2)
Calculate the electric field inside the wire (0.01 V/m)

21. Ohm’s Law
V = IR DV = IR V = Voltage (V) I = Current (A) R = Resistance (Ohms, W) (only works for metal conductors, not semiconductors (nonohmic))

22. Resistors Color coded to determine resistance
Devices that heat have high resistance (light bulbs, electric stoves, toasters)

23. A small flashlight bulb draws 300 mA from a 1.5 V battery.
Calculate the resistance of the bulb (5.0 W)
If the voltage dropped to 1.2 V and the resistance stayed at 5.0 W, what current would flow. (0.24 A)

24. Resistivity
R = rL A R = Resistance L = Length (longer wire, greater resistance) A = Area (wider wire, less resistance) r = Resistivity of the material

26. What is the resistance of a 2. 00mm diameter, 10. 0 meter copper wire
What is the resistance of a 2.00mm diameter, 10.0 meter copper wire? A = pr2 = (3.14)(0.001 m)2 = 3.14 X 10-6 m2 R = rL = (1.68 X 10-8 Wm)(10.0 m) A (3.14 X 10-6 m2) R = W of 53.5 m W

27. A speaker wire must be 20.0 m long and have a resistance of less than 0.100 W per wire.
What diameter copper wire should be used? (2.06 mm)
What is the voltage drop across each wire at a current of 4.00 A? (0.40 V)

28. A wire of length L is stretched to twice its normal length.
Calculate the new cross sectional area (assume the volume does not charge (Anew =1/2A)
Calculate the new resistance (Rnew = R)

29. R = rL A A = rL R A = [(1. 68 X 10-8 Wm)(20. 0 m)]/0. 100 W A = 3
R = rL A A = rL R A = [(1.68 X 10-8 Wm)(20.0 m)]/0.100 W A = 3.36 X 10-6 m2 A = pr2 r = (A/p)1/2 r = (3.36 X 10-6 m2 /3.14)1/2 = 1.03 X 10-3 m D = 2r = 2.06 X 10-3 m or 2.06 mm

30. Resistance and Temperature
Metals
Resistance increases with temp.
Atoms more disorderly
Interferes with flow of electrons
Semiconductors
Resistance sometimes decreases with temperature
Some electrons become excited and able to flow

31. Superconductivity
Superconductivity – resistance of a material becomes zero
No loss of current over a wire
Generally near absolute zero
Record as of 2007 is 138 K
Maglev trains