Chapter 20 Electric Current and Resistance
Units of Chapter 20 Batteries and Direct Current Current and Drift Velocity Resistance and Ohm’s Law Electric Power
20.1 Batteries and Direct Current Electric current is the flow of electric charge. A battery is a source of electric energy—it converts chemical energy into electric energy.
20.1 Batteries and Direct Current In a complete circuit, electrons flow from the negative electrode to the positive one. The positive electrode is called the anode; the negative electrode is the cathode. A battery provides a constant source of voltage—it maintains a constant potential difference between its terminals.
20.1 Batteries and Direct Current The potential difference between the battery terminals when the battery is not connected to anything is called the electromotive force, emf.
20.1 Batteries and Direct Current The actual terminal voltage of the battery is always less than the emf, due to internal resistance. Usually the difference is very small.
20.1 Batteries and Direct Current The actual terminal voltage of the battery is always less than the emf, due to internal resistance. Usually the difference is very small. V term = - (IR) Where is the emf, V term is the terminal voltage, & IR is the internal voltage drop More on this later… 20.3
20.1 Batteries and Direct Current When batteries are connected in series, the total voltage is the sum of the individual voltages.
20.1 Batteries and Direct Current When batteries of equal voltage are connected in parallel, the total voltage does not change; each battery supplies part of the total current.
20.1 Batteries and Direct Current
20.1 Current and Drift Velocity Current is the time rate of flow of charge. SI unit of current: the ampere, A
20.1 Current and Drift Velocity Historically, the direction of current has been taken to be from positive to negative; this is opposite to the way electrons flow. However, this seldom matters.
20.1 Current and Drift Velocity Electrons do not flow like water in a pipe. In the absence of voltage, they move randomly at high speeds, due to their temperature. When a voltage is applied, a very small drift velocity is added to the thermal motion, typically around 1 mm/s; this is enough to yield the observed current.
20.2 Resistance and Ohm’s Law If there is a potential difference across a conductor, how much current flows? The ratio between the voltage and the current is called the resistance. SI unit of resistance: the ohm, Ω
20.2 Resistance and Ohm’s Law An ohmic material is one whose resistance is constant.
20.2 Resistance and Ohm’s Law Ohm’s law is valid only for ohmic materials: The resistance of a particular object depends on its length, cross- sectional area, material, and temperature.
20.3 Resistance and Ohm’s Law As expected, the resistance is proportional to the length and inversely proportional to the cross-sectional area (why?): The constant ρ is called the resistivity, and is characteristic of the material.
20.3 Resistance and Ohm’s Law In this table, you can easily see the differences between the resistivities of conductors, semiconductors, and insulators.
20.4 Electric Power Power, as usual, is the rate at which work is done. For work done by electricity: Rewriting, For ohmic materials, we can write:
20.4 Electric Power So, where does this power go? It is changed to heat in resistive materials.
20.4 Electric Power Electric appliances are rated in watts, assuming standard household voltage.
20.4 Electric Power
The electric company typically bills us for kilowatt-hours (kWh), a unit of energy. We can reduce our energy usage by buying efficient appliances.
Review of Chapter 20 A battery produces emf; positive terminal is the anode, negative is the cathode. emf is measured in volts; it is the number of joules the battery supplies per coulomb of charge. An electric current can exist only in a complete circuit. Resistance:
Review of Chapter 20 Ohm’s law is obeyed if the resistance is constant: The resistance of an object depends on its length, cross-sectional area, and resistivity.
Review of Chapter 20 Power is the rate at which work is done.