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Current and Resistance
Chapter 31
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Batteries
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- + 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
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Circuits
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Drift Speed Electrons do not flow through wires like pipes
Electric field gives direction to the random motion of electrons. (vD = drift speed)
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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
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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)
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Conventional Current Flows positive to negative
Opposite of electron flow (electron current)
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Current (I) Current – Net amount of charge per unit time
1 coulomb/second = 1Ampere I = DQ Dt I = dQ I = eie electron current dt
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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)
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Current Density (J)
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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)
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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)
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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
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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
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Current Density (J) Conductivity (s) Resistivitiy (r) Current density
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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)
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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)
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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))
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Resistors Color coded to determine resistance
Devices that heat have high resistance (light bulbs, electric stoves, toasters)
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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)
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Resistivity R = rL A R = Resistance L = Length (longer wire, greater resistance) A = Area (wider wire, less resistance) r = Resistivity of the material
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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
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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)
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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)
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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
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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
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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
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