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Capacitance and Dielectrics áCapacitance áCapacitors in combination #Series #Parallel áEnergy stored in the electric field of capacitors and energy density.

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Presentation on theme: "Capacitance and Dielectrics áCapacitance áCapacitors in combination #Series #Parallel áEnergy stored in the electric field of capacitors and energy density."— Presentation transcript:

1 Capacitance and Dielectrics áCapacitance áCapacitors in combination #Series #Parallel áEnergy stored in the electric field of capacitors and energy density áDielectrics áDielectric Strength Lesson 4

2 Field Above Conductor Field above surface of charged conductor Does not depend on thickness of conductor E  Q A  0    0

3 charge =  Area A E conductor in electrostatic equilibrium  A  0  E  d A  EdA A  closed cylinder   EdA A   E   A A  0    0

4 Charged Plates + - d E W  Fd  QEd  U   U   U    V  Ed  V   V  +Q-Q

5  Potential drops Ed in going from + to -  V - is Ed lower than V + PD between Plates

6  How does one make such a separation of charge?  Must move positive charge  Work is done on positive charge in producing separation Q -Q +Q F Work Done in Moving Charge

7  What forms when we have separation of charge?  An Electric Field +Q -Q-Q E Electric Field

8 Capacitorb áThe work done on separating charges to fixed positions áis stored as potential energy áin this electric field, which can thus DO work CAPACITOR áThis arrangement is called a CAPACITOR

9  How do we move charge?  With an electric field conduction path  along a conduction path Moving Charge

10 Picture

11  The charge separation is maintained  by removing the conduction path  once a charge separation has been produced  An electric component that does this is called A Capacitor Charge Separation

12 Capacitor Symbol

13 + - Battery Symbol

14 Charging Capacitor Can charge a capacitor by connecting it to a battery + + - -

15 Capacitance  Plates are conductors  Equipotential surfaces  Let V = P.D. (potential difference) between plates  Q (charge on plates) ~ V (why?)  Thus Q = CV CAPACITANCE  C is a constant called CAPACITANCE

16 SI Units

17 Calculation of Capacitance  assume charge Q on plates  calculate E between plates using Gauss’ Law  From E calculate V  Then use C = Q/V

18 Capacitors

19 Electric Field above Plates

20 Calculating Capacitance in General going from positive to negative plate  V= V f  V i  E  d s i f   0 E  d s  0 choose path from+ plate to- plate  V = -V (PD across plates) ThusV=Eds + -  (choose path|| to electric field) C  EA  0 Eds + -  In order that

21 for Parallel Plates Capacitor - + C  Q V  EA  0 Eds   EA  0 Ed  A  0 d

22 C  Q V  2  0 L ln b a       a = radius of inner cylinder b = radius of outer cylinder L = length of cylinder for Cylindrical Capacitor

23 Combination of Capacitors Parallel Combinations of Capacitors in equilibrium  Parallel  same electric potential felt by each element  Series  electric potential felt by the combination is the sum of the potentials across each element

24 Picture

25 Calculation of Effective Capacitance

26 Combination of Capacitors Series

27 Picture Net charge zero Why are the charges on the plates of equal magnitude ?

28 Calculation of Effective Capacitance I  If net charge inside these Gaussian surfaces is not zero  Field lines pass through the surfaces  and cause charge to flow  Then we do have not equilibrium

29 Calculation of Effective Capacitance II

30 Question I Is this parallel or series? =

31 Question II Is this parallel or series? + + - -

32 Work Done in Charging Capacitor Work done in charging capacitor I + + - - q

33 Calculation

34 Energy Density

35 Dielectrics

36 Picture

37

38 Polarization

39 Induced Electric Field Polarization

40 Dielectric Constant

41 Permitivity

42 Permitivity in Dielectrics For conductors(not dielectrics )  For regions containing dielectrics all electrostatic equations containing  0 are replaced by  e.g. Gauss' Law  E  d A  Q  surface 

43 Dielectric Strength  The Dielectric Strength of a non conducting material is the value of the Electric Field that causes it to be a conductor.  When dielectric strength of air is surpassed we get lightning Dielectric Strength


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