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Capacitance

Capacitance. Revised: 2014Feb17. Sections 21.7-9 and 23.8 in book. 2. IV. Capacitance. The “Electric Condenser” Dielectrics Energy in Electric Field. 3. A. The Electric Condenser. History of the Capacitor Calculation from Geometry Capacitors in Circuits. 4.

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Capacitance

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  1. Capacitance Revised: 2014Feb17 Sections 21.7-9 and 23.8 in book

  2. 2 IV. Capacitance • The “Electric Condenser” • Dielectrics • Energy in Electric Field

  3. 3 A. The Electric Condenser • History of the Capacitor • Calculation from Geometry • Capacitors in Circuits

  4. 4 1. History of the Capacitor • The Leyden Jar • Parallel Plate Capacitor • The Law of Capacitance

  5. 5 1a. Leyden Jar Invented in 1745 by Pieter van Musschenbroek (1700–1748) as a device to store “electric fluid” in a bottle

  6. 6 “Battery” of Leyden Jars • (1747?) Daniel Gralath was the first to combine several jars in parallel into a "battery" to increase the total possible stored charge. • He demonstrated its effects on a chain of 20 persons

  7. 7 1b. Aepinus Condenser (c1759) The first parallel capacitor (called a “condenser”) was probably developed by Franz Aepinus (around 1759). The spacing could be changed and materials inserted between the plates.

  8. 8 Charge is stored on glass • Classic Leyden Jar was filled with water. • Franklin showed (before 1749) coating inside and outside of jars with metal foil worked better. Water is unneeded! • Invented the dissectible Leyden jar showing charge remained on glass, not on the metal • Invented the “Franklin Square”, a capacitor using a square glass plate.

  9. 9 1c. Alessandro Volta’s law of Capacitance • 1776 Law of Capacitance: Stored charge is proportional to applied voltage: Q=VC • Capacitance “C” is measure of ability to store charge. • Units: Farad=Coul/Volt • Common unit is “microfarad” • 1782 called the device a “condenser” (derived from the Italian condensatore) Volta: 1745-1827

  10. 10 2. Calculation of Capacitance Capacitance is a function only of the geometry of the device • Parallel Plate Capacitor • Cylindrical Capacitor • Spherical Capacitors

  11. 11 2a. Parallel Plate Capacitor • Voltage between plates: V=Ed • Electric Field:(Gauss’s law) • Capacitance Formula:

  12. 12 2bi What is capacitance of a single ball? • Recall voltage around a spherical ball is inversely proportional to radius • Let ball be radius “a”, the voltage at the surface is: • Hence capacitance is:

  13. 13 2bii. Spherical Capacitor • Faraday experimented with spherical capacitors. The capacitance is given by the formula below where “a” is the radius of inner conductor, “b” is the (inner) radius of the outer conductor.

  14. 14 2c. Cylindrical Capacitor • A coaxial cable is an example of a cylindrical capacitor. The capacitance is given by the formula below where “a” is the radius of inner conductor, “b” is the (inner) radius of the outer conductor and the length is “L”.

  15. 15 3. Capacitors in Circuits • Parallel • Series • RC Circuits

  16. 16 3a. Capacitors in Parallel • Capacitors in Parallel add: C = C1+C2 • Its like 2 tanks next to each other have more capacity. • Elements in parallel have same voltage, hence:

  17. 17 3b. Capacitors in Series • Capacitors in series will have the same charge, but the total voltage is the sum. So we have: Alternate form:

  18. 18 3c. RC Circuits (notes on board)[section 23.8 in Knight] • Consider a capacitor “C” as a “tank” being filled up with charge from a battery (“pump”). The resistor “R” constricts the flow of current. • After one “time constant” =RC, the capacitor will reach 63% of the battery’s voltage

  19. 19 3c. Discharging RC Circuit[section 23.8 in Knight] • Discharging a capacitor through a resistor, the voltage will fall off as an exponential decay. • After one “time constant” =RC, the capacitor drop to 37% of its original voltage. • Units: OhmFarad=Second

  20. 20 B. Dielectrics • Dielectric Constant • Electric Polarization • Dielectric Strength

  21. 21 1. Dielectric Constant • 1837 Faraday finds inserting an insulator (aka “dielectric”) between plates will increase capacitance • Increase by factor “K” (dielectric constant) • Air: K=1.00059 • Water: K=80 • The electric field (and hence voltage) is reduced by a factor of “K”

  22. 22 2. Electric Polarization • 1833 Faraday shows an electric field “induces” dipoles in an insulator • This dipole field opposes the applied field, and so the net field is reduced by a factor of “K” • Inside of dielectric, Gauss’s law is valid if you replace 0→=K0

  23. 23 3. Dielectric Strength • Definition is the maximum electric field before material ionizes (dielectric breakdown) • For Air: 3,000,000 volts/meter • This puts a limit on the maximum charge a capacitor can hold.

  24. 24 C. Energy in Capacitors • Energy Storage Formula • Electric Stress • Energy stored in E field

  25. 25 1. Capacitive Energy • Recall spring: F=kx, energy stored: • For capacitor: Q=CV, energy stored • Charging a capacitor is like filling a tank. As charge added, voltage increases, so it takes more work to add additional charge.

  26. 26 2. Electric Stress a) Charge on surface of conductor (i.e. plate of capacitor) experiences “pressure” due to the electric field that wants to tear it apart: • Pressure: • Recall from Gauss’s law the electric field near a conductor with surface charge: • Hence:

  27. 27 2b. Force Between Plates • The opposite charges on the parallel plates of a capacitor attract each other. • Force must be equal to change in energy: • There are two ways to argue this. The first is to have a charged capacitor, disconnected from the battery, so that the charge is constant. Then since,

  28. 28 2c. Force Between Plates • We get a different answer however if the capacitor is connected to a battery while the plates are pulled apart. • Here the voltage will remain constant, but the charge will change as the plates are pulled apart (charge will be forced out because the capacitance decreases with increase in distance) • Ouch, need calculus to derive the force between the plates:

  29. 29 3. Energy Stored in Electric Field a) Energy in terms of Electric Field between plates: • Energy in Capacitor: • Voltage: • Relate Charge to Field(in dielectric): • Energy=

  30. 30 3b. Energy Density • Divide by the volume (Ad) to get the energy per unit volume: • Interpret that the energy IS stored in the electric field

  31. 31 3c. Energy in Dielectric • By inserting a dielectric the capacitance is increased. • If capacitor is charged (but not connected to battery), then inserting dielectric will reduce the electric field by a factor of “K”, reducing the energy. Hence it will suck a dielectric into the plates. • If capacitor is connected to a battery however, then the voltage is constant (E field unchanged) and so energy increases (because of increase in permittivity). Hence will push dielectric out!

  32. 32 References • Misc • http://www.circuitstoday.com/working-of-a-capacitor • static electricity animations at • http://www.physicsclassroom.com/ • History at: • http://www.hkcapacitor.com/capacitor/Capacitor-History.html • http://www.sparkmuseum.com/LEYDEN.HTM • http://maxwell.byu.edu/~spencerr/phys442/node4.html • http://en.wikipedia.org/wiki/Timeline_of_Fundamental_Physics_Discoveries

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