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Chapter 19: Q35P (page 797)

Which of the following statements about the discharging of a capacitor through a light bulb are correct? Choose all that are true. (1) The fringe field of the capacitor decreases as the charge on the capacitor plates decreases. (2) Electrons flow across the gap between the plates of the capacitor, thus reducing the charge on the capacitor. (3) The electric field at a location inside the wire is due to charge on the surface of the wires and charge on the plates of the capacitor. (4) Electrons in the wires flow away from the negative plate toward the positive plate, reducing the charge on the plates.

Short Answer

Expert verified

The correct statements are:

(1) The fringe field of the capacitor decreases as the charge on the capacitor plates decreases.

(4) Electrons in the wires flow away from the negative plate toward the positive plate, reducing the charge on the plates.

Step by step solution

01

Given data

The following statements are provided:

(1) The fringe field of the capacitor decreases as the charge on the capacitor plates decreases.

(2) Electrons flow across the gap between the plates of the capacitor, thus reducing the charge on the capacitor.

(3) The electric field at a location inside the wire is due to charge on the surface of the wires and charge on the plates of the capacitor.

(4) Electrons in the wires flow away from the negative plate toward the positive plate, reducing the charge on the plates.

02

Discharging of a capacitor

While a capacitor discharges, electrons on the negative plate are forced across the circuit by the fringe field of the capacitor. The electrons move to the positive terminal thus reducing the charge on both plates and hence reducing the fringe field. This continues until the capacitor is fully discharged.

03

Determination of whether the provided statements are true or false

During discharging of a capacitor, electrons move from the negative to the positive plate thus reducing the charge accumulation in both plates and hence reducing the fringe field. Thus, statement (1) is true.

No charge flows across the gap between the two plates of a capacitor. Thus, statement (2) is false.

While discharging, the only field in the wires is the field created due to the charge difference between the plates of a capacitor. Thus, statement (3) is false.

Electrons do flow from the negative plate to the positive plate while discharging, thus reducing the charge on each plate. Hence, statement (4) is true.

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Most popular questions from this chapter

In copper at room temperature, the mobility of mobile electrons is about 4.5×10-3(m/s)V/m,and there are about8×1028mobile electrons perm3Calculate the conductivityσand include the correct units. In actual practice, it is usually easier to measure the conductivityσand deduce the mobilityufrom this measurement.

Work and energy with a capacitor: A capacitor with capacitance Chas an amount of charge q on one of its plates, in which case the potential difference across the plates is Δ³Õ=q/C (definition of capacitance). The work done to add a small amount of charge dq when charge the capacitor is dqΔ³Õ=dqq/C. Show by integration that the amount of work required to charge up the capacitor from no charge to final charge Q is 12(Q2/C). Since this is the amount of work required to charge the capacitor, it is also the amount of energy stored in the capacitor. Substituting Q=CΔ³Õ, we can also express the energy as 12CΔ³Õ2.

A particular capacitor is initially charged. Then a high-resistance Nichrome wire is connected between the plates of the capacitor, as shown in Figure 19.69. The needle of a compass placed under the wire deflects 20°to the east as soon as the connection is made. After 60sthe compass needle no longer deflects.

(a)Which of the diagrams in Figure 19.69 best indicates the electron current at three locations in this circuit? (1) 0.01safter the circuit is connected, (2) 15s after the circuit is connected, (3) 120s after the circuit is connected.

(b)Which of the diagrams in Figure 19.70 best indicates the net electric field inside the wire at three locations in this circuit? (1) 0.01s after the circuit is connected, (2) 15safter the circuit is connected, (3) 120s after the circuit is connected.

The insulating layer between the plates of a capacitor not only holds the plates apart to prevent conducting contact but also has a big effect on charging. Consider two capacitors whose only difference is that capacitor number has nothing between the plates, while capacitor number has a layer of plastic in the gap (Figure 19.57). They are placed in two different circuits having similar batteries and bulbs in series with the capacitor.

Show that in the first fraction of a second the current stays more nearly constant (decreases less rapidly) in the circuit with capacitor number . Explain your reasoning in detail. Hint: Consider the electric fields produced in the nearby wires by this plastic-filled capacitor. Suppose that the plastic is replaced by a different plastic that polarizes more easily. In the same circuit, would this capacitor keep the current more nearly constant or less so than capacitor ?

A more extensive analysis shows that this trend holds true for the entire charging process: the capacitor containing an easily polarized insulator ends up with more charge on its plates. The capacitor you have been using is filled with an insulator that polarizes extremely easily.

Why can birds perch on the bare wire of a power line without being electrocuted?
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