1. Capacitance Electric fields can be used to store energy. How? Any two conductors near each other form a CAPACITOR, we say there is “capacitance in the system”
2. Capacitance A capacitor is an energy storage device. A capacitor can store charge: q is removed from one side of the capacitor and placed onto the other, leaving one side with (-q) and the other side with (+q). We have to do WORK to do this. If we connect the two conductors with a wire, the charges flow to make the potential difference between conductors = 0. When this happens, energy is released
4. Capacitance Charge that can be stored in capacitor is proportional to the potential (voltage) which is pushing the charge into the conductors Constant of proportionality is “C”, the capacitance Definition of capacitance:
5. Capacitance C is just a function of geometry between two conductors General method to calculate capacitance: a) Assume a charge on the conductors b) Calculate the voltage difference due to the charge ` c) The Ratio Q/V is the capacitance The unit of capacitance is called the Farad (F) One Farad is equal to one Coulomb per Volt ( F = C / V )
9. Energy Stored in Capacitors Energy stored in a capacitor = like a stretched spring has potential energy associated with it. How much work is required to charge a capacitor? It’s the work to move charges from one plate to another, one at a time. Moving first electron: almost no potential difference, not a lot of work. But with more and more electrons: the potential difference V gets bigger and bigger, so more work is required
10. Energy Stored in Capacitors Each electron has to do q e x V of work to get across. Total work is total charge x average potential difference: The energy stored in a capacitor is the energy required to charge it:
11. Electric field energy Another way to think of the energy stored in a in a charged capacitor: Imagine the stored energy is contained in the space between the plates We can calculate an energy DENSITY (Joules per volume): The volume between the plates is A d. Then the energy density (u) is But we know and so This is an important result because it tells us that empty space can contain energy, if there is an electric field in the "empty" space. If we can get an electric field to travel (or propagate) through empty space we can send or transmit energy! This is achieved with light waves (or microwaves or radio waves or whatever)
12. Dielectrics “ Dielectric” is another word for insulator, a material that does not allow charges to move easily through it. Why do we write 0 , with a little 0 subscript? Because other materials (water, paper, plastic, even air) have different permittivities = k 0 . Here, k is called the dielectric constant . In all of our equations where you see 0 , you can substitute 0 when considering some other materials
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14. Dielectrics A dielectric in an electric field becomes polarized; this allows it to reduce the electric field in the gap for the same potential difference.
15. Dielectrics Inserting a dielectric into a capacitor while either the voltage or the charge is held constant has the same effect – the ratio of charge to voltage increases.
16. Combining capacitances Capacitors in series all have the same charge; the total potential difference is the sum of the potentials across each capacitor. Note that this gives the inverse of the capacitance.
17. Combining capacitances Capacitors in parallel all have the same potential difference; the total charge is the sum of the charge on each.
18. Combining capacitances We can picture capacitors in parallel as forming one capacitor with a larger area:
19. Review of Capacitance: Capacitance of a parallel-plate capacitor: Energy stored in a capacitor: A dielectric is a nonconductor; it increases capacitance. Dielectric constant:
Notas del editor
Capacitors consist of two chunks of conductor, separated by a volume of dielectric (insulator). Any two such chunks form a capacitor. Here are some examples.