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W05D2 Dielectrics and Conductors as Shields. Today’ s Reading Assignment: Course Notes Sections 5.4, 5.6, 5.8-5.9. Math Review Week 06 Tuesday 9-11 pm in 26-152 PS 5 due W05 Tuesday at 9 pm in boxes outside 32-082 or 26-152 Add Date Week 05 Friday
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W05D2Dielectrics and Conductors as Shields Today’s Reading Assignment: Course Notes Sections 5.4, 5.6, 5.8-5.9
Math Review Week 06 Tuesday 9-11 pm in 26-152 PS 5 due W05 Tuesday at 9 pm in boxes outside 32-082 or 26-152 Add Date Week 05 Friday W05D3 Reading Assignment: Friday Problem Solving Capacitance and Dielectrics Course Notes Sections 5.6, 5.8-5.9 Announcements
Outline Dielectrics Electric Fields in Matter Conductors as Shields
Dielectrics A dielectric is a non-conductor or insulator Examples: rubber, glass, waxed paper When placed in a charged capacitor, the dielectric reduces the potential difference between the two plates HOW???
Molecular View of Dielectrics Polar Dielectrics : Dielectrics with permanent electric dipole moments Example: Water
Molecular View of Dielectrics Non-Polar Dielectrics Dielectrics with induced electric dipole moments Example: CH4
Dielectric in Capacitor Potential difference decreases because dielectric polarization decreases Electric Field!
Dielectric Constant Dielectric weakens original field by a factor Dielectric Constant Dielectric constants Vacuum 1.0 Paper 3.7 Pyrex Glass 5.6 Water 80
Group Problem: Induced Surface Charge Density A dielectric material with constant completely fills the space between two conducting plates that have a surface charge densities as shown in the figure. Induced surface charge densities appear on the surfaces of the dielectric. Find an expression for in terms of and .
Demonstration:Parallel Plate Capacitorwith Dielectric E5 http://tsgphysics.mit.edu/front/?page=demo.php&letnum=E%205&show=0
Dielectric in a Capacitor Q0 = constant after battery is disconnected Upon inserting a dielectric free charge on plates does not change, potential decreases, capacitance increases
Dielectric in a Capacitor V0 = constant when battery remains connected Upon inserting a dielectric free charge on plates increase
Gauss’s Law with Dielectrics In both cases:
+ + + + + + + + - - - - - - - - Concept Question: Dielectric A parallel plate capacitor is charged to a total charge Q and the battery removed. A slab of material with dielectric constant is inserted between the plates. The charge stored in the capacitor • Increases • Decreases • Stays the Same
+ + + + + + + + - - - - - - - - Concept Question Answer: Dielectric Answer: 3. Charge stays the same Since the capacitor is disconnected from a battery there is no way for the amount of charge on it to change.
+ + + + + + + + - - - - - - - - Concept Question: Dielectric A parallel plate capacitor is charged to a total charge Q and the battery removed. A slab of material with dielectric constant in inserted between the plates. The energy stored in the capacitor • Increases • Decreases • Stays the Same
Concept Question Answer: Dielectric Answer: 2. Energy stored decreases The dielectric reduces the electric field and hence reduces the amount of energy stored in the field. The easiest way to think about this is that the capacitance is increased while the charge remains the same so Also from energy density:
+ + + + + + + + - - - - - - - - Concept Question: Dielectric A parallel plate capacitor is charged to a total charge Q and the battery removed. A slab of material with dielectric constant in inserted between the plates. The force on the dielectric • pulls in the dielectric • pushes out the dielectric • is zero
Concept Question Answer: Dielectric Answer: 1. The dielectric is pulled in We just saw that the energy is reduced by the introduction of a dielectric. Since systems want to reduce their energy, the dielectric will be sucked into the capacitor. Alternatively, since opposing charges are induced on the dielectric surfaces close to the plates, the attraction between these will lead to the attractive force.
Concept Question: Point Charge in Conductor A point charge +Q is placed inside a neutral, hollow, spherical conductor. As the charge is moved around inside, the surface charge density on the outside • is initially uniform and does not change when the charge is moved. • is initially uniform but does become non-uniform when the charge is moved. • is initially non-uniform but does not change when the charge is moved. • is initially non-uniform but does change when the charge is moved.
Concept Question Answer: Q in Conductor Answer: 1 is initially uniform and does not change when the charge is moved. E = 0 in conductor -Q on inner surface Charge conserved +Q on outer surface E = 0 in conductor No “communication” between –Q & +Q + Q uniformly distributed
+Q Concept Question: Point Charge in Conductor A point charge +Q is placed inside a neutral, hollow, spherical conductor. As the charge is moved around inside, the electric field outside • is zero and does not change • is non-zero but does not change • is zero when centered but changes • is non-zero and changes
Concept Question Answer: Q in Conductor Answer: 2. is non-zero but does not change. E = 0 in conductor -Q on inner surface Charge conserved +Q on outer surface E = 0 in conductor No “communication” between –Q & +Q + Q remains uniformly distributed so E stays unchanged
Shielding By Conducting Shell: Applet Charge placed INSIDE induces balancing charge ON INSIDE. Electric field outside is field of point charge. http://web.mit.edu/viz/EM/visualizations/electrostatics/ChargingByInduction/shielding/shielding.htm
Shielding by Conducting Shell: Applet Charge placed OUTSIDE induces charge separation ON OUTSIDE. Electric field is zero inside. http://web.mit.edu/viz/EM/visualizations/electrostatics/ChargingByInduction/shielding/shielding.htm
Demonstration:Faraday Cage D33 http://tsgphysics.mit.edu/front/?page=demo.php&letnum=D%2033&show=0