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Agenda Today –Chapter 24 (Finish Fri & Start 25) HMWK Due Fri Return Quiz Friday Reading –Finish ch. 24 by Friday –Skim 25 (at least last page) Friday.

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Presentation on theme: "Agenda Today –Chapter 24 (Finish Fri & Start 25) HMWK Due Fri Return Quiz Friday Reading –Finish ch. 24 by Friday –Skim 25 (at least last page) Friday."— Presentation transcript:

1 Agenda Today –Chapter 24 (Finish Fri & Start 25) HMWK Due Fri Return Quiz Friday Reading –Finish ch. 24 by Friday –Skim 25 (at least last page) Friday –Read 25 by Monday

2 Field vs. Potential Turns Scalar into Vector

3 Field vs. Potential Gradient: Think Slope of PE plot 3D Fun Potential surrounding + & - charge pair Slope at any given point gives Electric Field

4 Simple Example Gravity of course

5 Force from PE Field is same (w.o. the “m”)

6 Spherical Case Normally quite complicated Wait till calc 3 Radial component only:

7 Fields in a material? Electric Field changes in a material Example: Metal field = 0 Insulators change as well Interaction of neutral object with a field? Polarization Polarization takes energy (lining up atoms) Some of the energy in the field goes to polarizing material Reduces the effective strength of a field

8 Mathematically Electric Field of a point charge Equivalent Equations Epsilon (  ) is permittivity How easily field permeates a material  is a material dependent constant  in vacuum is one  in air is one  in materials (insulators) is > 1

9 Dielectrics Materials used specifically for their permittivities (  or  0 ) Talked about when dielectric properties are important

10 Dielectric Breakdown When electric field too large Strips electrons from material components Arcing – shorting – lightning Damaging to components (& people!)

11 How many volts in static electricity? Dielectric Breakdown in air ~ 3x10 6 V/m Units for field V/m or N/C (same thing) Most shocks between mm & cm Assume field constant –Big || plates = finger & cat for example Field = Breakdown field V ranges from 1 to 10 kV Deadly?

12 Dielectric Usage Stores Field energy in form of polarization Can be used as electrical energy storage Capacitors

13 Simplest Form: || Plate Apply Voltage Across Parallel Plates V = Ed E (plate) =    E (Between) =     = Q/A Infinite just approximation E = Q/(A  0 ) V = Ed V = Qd / (A  0 )

14 Simplest Form: || Plate Apply Voltage Across Parallel Plates V = Qd / (A  0 ) Capacitance = Ability to store Charge from V Q = V C [C is capacitance] V = Q / C || plate: C = A  0 /d Examine parameters Geometric & material only, no field dep.

15 Energy Storage: Capacitor Consider how much energy it takes to move charges from one plate to another “Assemble” Charges Work done in moving charges stored as Potential Energy

16 Energy Storage: Capacitor Can Apply Top Equation to Bottom Mix & Match, Q,V,C As usual, ½  Integration

17 Other Geometries Spherical, other all have different formulas for capacitance Universal: –C depends only on dielectric & geometry –Q = VC –PE = Q 2 /2C

18 Agenda Today –Chapter 24 (Finish Fri & Start 25) HMWK Due Fri Return Quiz Friday Reading –Finish ch. 24 by Friday –Skim 25 (at least last page) Friday –Read 25 by Monday

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