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Measuring current. Electric current: rate of flow of electrons past a specific point in a circuit Measured with: Ammeter Symbol: I Unit: ampere (A) 1 A = 6.2 x 10 18 electrons/s = 1 C/s C= coulomb. Ammeter.
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Measuring current • Electric current: rate of flow of electrons past a specific point in a circuit • Measured with: Ammeter • Symbol: I • Unit: ampere (A) • 1 A = 6.2 x 1018 electrons/s = 1 C/s C= coulomb
Ammeter • Must be connected IN SERIES with a load to measure the current through that load
Potential Difference • The difference in electric potential energy per unit charge measured at two different points • the force that moves electrons • the amount of energy given to electrons to move them • also called Voltage • Measured with: Voltmeter • Symbol: V Unit: volt (V)
There is potential difference between the two terminals of an electric cell • Electrons leave the negative terminal with electric potential energy to operate the load • They return to the positive terminal with no potential energy because it was used to energize the load • The electrons are “re-energized” in the electric cell
Electrons leaving electric cell have a lot of potential energy Electrons returning to the positive terminal have lost their potential energy/ given it to the lamp/load
Voltmeter • The device used to measure potential difference • Must be connected in PARALLEL with a load or energy source • The negative side of the voltmeter is connected to the negative side of the battery + - - +
Electrical Resistance • The ability of a material to oppose the flow of electric current; measured in ohms () • All materials have some internal resistance • Greater resistance lower current warmer material • Electrons flowing through the material bump into atoms that make up the material and some of the electrical energy they carry is converted into thermal energy
Factors that Affect Resistance • Type of material • Conductors such as copper and silver allow electrons to pass through easily and thus has low electrical resistance 2) Cross-sectional area • Wire’s with a larger diameter have lower resistance than narrower wires • Electrons have more room to move freely d R
3) Length • Internal resistance increases as the wire length increases because electrons have to travel through more material • l R Ex. Extension cords are made using large-diameter wire to reduce the resistance as result of their length. If not, they would pose a fire threat due to overheating
4) Temperature • As electrons move through the wire they bump into atoms and release thermal energy • The wire’s atoms gain energy, vibrate faster and more collisions result • More collisions increased resistance • T R
Ohmmeter • Device used to measure resistance across a load • Must be connected in PARALLEL with a load • The ohmmeter provides an electric current therefore the circuit should not be powered to measure resistance
How Stuff Works - Toaster • When a toaster is plugged in current flows through a copper wire with little resistance • The heating element is made up of an alloy with much greater resistance • The electrons slow down, bump into each other a lot and release thermal and light energy – the glowing element • Same is true for elements on the stove
Resistors in Circuits • An electrical device that reduces current in a circuit • Used to adjust brightness of lamps, to protect devices from current overload
Potential difference/voltage (V): The difference in electric potential energy per unit charge measured at two different points • Electrical Resistance (R): the ability of a material to oppose the flow of electric current; measured in ohms () • Electric current: rate of flow of electrons past a specific point in a circuit
Ohm’s Law • Georg Ohm discovered a mathematical relationship between potential difference and current in the 1800s • R = V / I I = V / R V = I x R • As the potential difference across a load increases, so does the current
Sample Problem – calculate the resistance across a load An electic cell with a potential difference of 6.0V is connected in a circuit with a lamp. A current of 2.0 amperes flows. All the wires are resistance-free. What is the resistance of the lamp? V
V = I R R=V/I R = 6.0 V / 2.0 A R = 3.0 Therefore the resistance of the lamp is 3.0 Ohms
Sample Problem 2 – calculating the voltage across a load • A toaster oven has a 24. 0 resistor that has 5. 0 A of current going through it when the toaster is on. Calculate the potential difference across the resistor • R = 24. 0 • I = 5. 0 A • V = IR • V= (5. 0 A)(24. 0 ) • V= 120 V • The potential difference across the resistor is 120V
Sample Problem 3 – calculating the current across a load • A laptop computer adapter has a voltage of 19V. It has a resistance of 4.0Ω. The adapter gets warm when operating. Determine the current through the adapter. • R=4.0Ω • V=19V • I=V/R • =12V/4.0Ω • I=3.0A • Therefore the current through the adapter is 3.0A