Deck 16: Electric Potential, Energy, and Capacitance

Why is it dangerous to probe inside a television set even hours after it has been unplugged?

Sort these materials in order of increasing dielectric constant: paper, vacuum, air.

A charged capacitor stores energy, and when the Teflon dielectric between the plates is pulled out the energy stored more than doubles. Where did the extra energy come from?

For a pair of oppositely charged parallel plates, the negatively charged plate is at a lower electric potential than the positively charged one by an amount $\Delta$ V.

Negative charges, when released, accelerate toward regions of lower electric potential.

Electric potential decreases when moving farther from positive charges or nearer to negative charges.

Equipotential surfaces are always at right angles to the electric field.

An electron moving from the negative terminal to the positive terminal of a 12. volt battery gains (or loses) how much energy? (Be sure to indicate whether it is a gain or loss.)

A metal sphere of radius 80. mm is charged to a potential of -0.50 kV. With what velocity must an electron be fired toward the sphere if it is to just barely reach the sphere when started from a position 15. cm from the center of the sphere?

How much energy is necessary to place three charges, each of 2.0 ?C, at the corners of an equilateral triangle of side 2.0 cm?

Four charges of equal charge +q are placed at the corners of a rectangle of sides a and b. What is the potential at the center of the rectangle if q = 2.0 $\mu$ C, a = 30. mm, and b = 40. mm?

Starting from rest, a proton falls through a potential difference of 1.2 kV. What speed does it acquire?

What is the electric potential at the center of a hollow metal sphere of outside diameter 14. cm which holds a net charge of 3.3 $\mu$ C?

Charges 6.8 $\mu$ C, 6.1 $\mu$ C, and -1.5 $\mu$ C are brought from infinity to the respective vertices of an equilateral triangle with 11. cm sides.
(a) How much energy did it take to move the charges to the triangle vertices?
(b) What is the potential at the center of the triangle?

What charge appears on the plates of a 2.00 $\mu$ F capacitor when it is charged to 100. V?

A parallel plate capacitor is constructed with plate area of 0.40 m² and a plate separation of 0.10 mm. How much charge is stored on it when it is charged to a potential difference of 12 V?

When a 12.0 volt battery is connected to a 6.00 $\mu$ F capacitor:
(a) how much energy is stored?
(b) how much charge is stored on the positive plate of the capacitor?

A 0.67 $\mu$ F parallel plate capacitor has air between the plates with a separation of 0.33 mm.
(a) What is the plate area?
(b) What charge is on the plates when connected to a 3.0 volt battery?

A parallel plate capacitor is constructed with Teflon (dielectric constant 2.1) between the plates. This 12.6 ?F capacitor has been charged to 1.5 volts. The Teflon is then pulled out (removed).
(a) What charge was originally stored?
(b) After removing the Teflon, what potential is across the plates?

Given 3 capacitors: 4.00 $\mu$ F, 7.00 $\mu$ F, and 9.00 $\mu$ F; what is the equivalent capacity if they are connected in series?

Given 3 capacitors: 4.00 $\mu$ F, 7.00 $\mu$ F, and 9.00 $\mu$ F; what is the equivalent capacity if they are connected in parallel?

1.8 $\mu$ F and 3.6 $\mu$ F capacitors are connected in series and then charged by a 24. volt battery. The battery and capacitors are disconnected and the capacitors reconnected in parallel (plus to plus, minus to minus)
(a) What charge initially flowed from the battery to the series combination?
(b) What total charge is on the final positive plates?
(c) What final voltage is across the parallel combination?

A 4.0 $\mu$ F and a 1.0 $\mu$ F capacitor are connected in parallel and both are charged with a 12. volt battery. They are disconnected from the battery and reconnected positive side of the 1st to negative side of 2nd, and neg. side of 1st to pos. side of 2nd.
(a) How much was each charged when connected to the battery?
(b) After reconnecting, how much charge is stored?
(c) What potential exists across the final parallel combination?

Consider capacitors C₁, C₂, and C₃, which are connected in series in a closed loop. A switch is placed between C₁ and C₂. With the switch open, C₁ is charged to 12.0 volts by a battery. The battery is then disconnected and the switch is closed. Determine the final charge on each capacitor, and the potential difference across each, given that C₁ = 2.00 μF, and C₂ = C₃ = 3.00 μF.

A charge of 2.0 $\mu$ C flows onto the plates of a capacitor when it is connected to a12.V battery. How much work was done in charging this capacitor?

A parallel-plate capacitor has plates of area 0.20 m² separated by a distance of
1.0 mm. What is this capacitor's capacitance?

A 15. $\mu$ F capacitor is connected to a 50. V battery and becomes fully charged. The battery is removed and a slab of dielectric that completely fills the space between the plates is inserted. If the dielectric has a dielectric constant of 5.0, what is the voltage across the capacitor's plates after the slab is inserted?

A 15. $\mu$ F capacitor is connected to a 50. V battery and becomes fully charged. The battery is removed and a slab of dielectric that completely fills the space between the plates is inserted. If the dielectric has a dielectric constant of 5.0, what is the capacitance of the capacitor after the slab is inserted?