1. Chapter 27: Current and Resistance
In terms of the current density
For a uniform current density parallel to the area element
Ohm’s Law
Practical version where the resistance is

2. Ohmic material
Nonohmic material

3. Example Problem
Lightning strikes the ground with a current of 100 kA. A person and a cow are each a radial distance D=60.0 m from the lightning strike. The current spreads through the ground uniformly over a hemisphere centered on the strike point. The person’s feet are separated by radial distance rper=0.50 m; the cow’s front and rear hooves are separated by the radial distance rcow=1.50 m. The resistivity of the ground is gr=100 m. The resistance both across the person, between left and right feet, and across the cow, between front and read hooves, is R=4.00 k. What are the currents through the person and through the cow?

4. Microscopic Description of Current and Ohm’s Lawx
Consider a conductor with cross sectional area A and a segment length x
If there is no potential difference across it, the electric field in the wire is zero and therefore the current is zero
However, there are electrons moving within the conductor
These conduction electrons move in random directions, but at high speeds ~106 m/s

5. No net displacement of the electrons  no current  no electric field
However, if a V is applied then there is an electric field in the conductor and a current
Considering the current at a microscopic level, there is  a volume element of Ax  with n total number of charge carriers per unit volume  each with positive charge q
The total charge in the volume element is
They move with a constant speed, the drift speed vd

6. In a vacuum with a uniform electric field, electrons move in a straight line in the opposite direction of the field lines
However, in a conductor, the electrons travel for short distances (~40 nm), in random directions until they encounter and atom, where the electron is scattered in a random direction
Nevertheless, the electrons move slowly in the direction opposite the electric field at the drift speed (~10-4 m/s)
The drift speed of electrical conduction can be understood through the Drude model which applies classical mechanics

7. Example Problem 27.25
If the magnitude of the drift velocity of free electrons in a copper wire is 7.84x10-4 m/s, what is the electric field in the conductor?

8. Variation of Resistivity and Resistance with Temperature
The values of most physical properties of materials vary with temperature
For a conductor, it is found, over a limited temperature range, that this variation is linear in temperature
0 is the resistivity at room temperature T0=20 C and  is the temperature coefficient of resistivity. It is given in Table 27.1 and has units of 1/C

9. Example Problem 27.29
A certain light bulb has a tungsten filament with a resistance of 19.0  when cold and 140  when hot. Assume that the resistivity of tungsten varies linearly with temperature even over the large temperature involved here, and find the temperature of the hot filament. Assume the initial temperature is 20.0 C.

10. Power in Electrical Circuits
A circuit is a closed loop (usually consisting of high conductivity wire) with a battery and one or more circuit elements
We assume now that the resistance in the wire is small and can be neglected b a

11. Mechanical Analogy

12. Example Problem 27.36
A toaster is rated at 600 W when connected to a 120-V source. What current does the toaster carry, and what is its resistance?