Capacitors insulating dielectric Capacitors store charge. They have two metal plates where charge is stored, separated by an insulating dielectric. To.

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Presentation transcript:

Capacitors insulating dielectric Capacitors store charge. They have two metal plates where charge is stored, separated by an insulating dielectric. To charge a capacitor, it must be connected to a voltage supply. When a capacitor is connected to a battery, a current flows in he circuit until the capacitor is fully charged, and then stops. An equal but opposite charge builds up on each plate causing a potential difference across the two plates. No charge can flow between them because of the insulating dielectric. Electrons are attracted from this plate of the capacitor to the positive terminal of the cell. This leaves the plate ‘electron deficient’ and so it is positively charged. Electrons are repelled from the negative terminal of the cell and pushed onto this plate of the capacitor. The capacitor plate has an excess of electrons and so is negatively charged. + + e-e- e-e- e-e- e-e-

When the potential difference across the capacitor is equal to the potential difference across the battery, the current falls to 0 Initially, when charging a capacitor, the current through the circuit is high. As charge builds up on the plates, electrostatic repulsion makes it harder for electrons to be deposited on the negative plate. When the potential difference across the capacitor is equal to the potential difference across the battery, the current falls to 0 and the capacitor is fully charged. Capacitance is the charge stored per unit of potential difference across the capacitor. A capacitor has a capacitance of 1 farad is it stores 1 coulomb of charge per 1 volt potential difference across it. The unit of capacitance is the farad. A capacitor has a capacitance of 1 farad is it stores 1 coulomb of charge per 1 volt potential difference across it. Capacitances are usually measured in μF (x10 -6 ) nF (x10 -9 ) or pF (x )

Capacitors store Energy After a capacitor has been charged, electrical energy is stored by the capacitor. When the capacitor is allowed to discharge through a component, a bulb for example, the electrical energy will be converted into light and heat. When a capacitor is charged, work is done removing charge from one plate and depositing it on the other to charge the capacitor. The energy comes from the electrical energy of the battery, so the energy stored by a capacitor must be equal to the work done by the battery.

Capacitors in Parallel If two or more capacitors are put in a parallel circuit:  The potential difference across each capacitor is the same  The total charge stored by the capacitors is the sum of the charges  The total capacitance is the sum of all of the individual capacitances If two or more capacitors are put in a parallel circuit:  The potential difference across each capacitor is the same  The total charge stored by the capacitors is the sum of the charges  The total capacitance is the sum of all of the individual capacitances C total = C 1 + C 2 + C 3 Capacitors in Series If two or more capacitors are put in a series circuit:  The potential difference is shared between the capacitors  The total charge stored by the capacitors is the same  The total capacitance is less than the individual capacitances. If two or more capacitors are put in a series circuit:  The potential difference is shared between the capacitors  The total charge stored by the capacitors is the same  The total capacitance is less than the individual capacitances.

Exponential Decay When a capacitor is discharging, the graphs of charge, current and voltage against time follow an exponential decay. For a large value of C, a lot of charge is stored. It takes longer for the capacitor to discharge, so the time constant is large. With a large value of R, the current will be small, so again, the capacitor will take a long time to discharge and so the time constant will be large.

Using Capacitors… 1.Camera Flashes A camera’s flashgun is powered by a capacitor which is charged from the battery via a system that increases the voltage. When a picture is taken, the charge is releases and flows rapidly through the lamp producing a flash. 2. Lasers in Nuclear Fusion Capacitors are charged to thousands of volts. Their energy is released to power lasers whose flash forces the atomic nuclei of hydrogen together, causing them to fuse to form helium nuclei. The fusion of the nuclei releases energy. 3. Back up power supplies in computers Capacitors with a high capacitance but small volume are used as back up power supplies. They are charged up when the computer is in use, then if the battery or mains supply fails, they provide the electrical power needed to save data and shut the computer down safely.