Textbook Problem

Two square plates of sides ℓ are placed parallel to each other with separation d as suggested in Figure P25.39. You may assume d is much less than ℓ. The plates carry uniformly distributed static charges +Q₀ and −Q₀. A block of metal has width ℓ, length ℓ, and thickness slightly less than d. It is inserted a distance x into the space between the plates. The charges on the plates remain uniformly distributed as the block slides in. In a static situation, a metal prevents an electric field from penetrating inside it. The metal can he thought of as a perfect dielectric, with κ → ∞. (a) Calculate the stored energy in the system as a function of x. (b) Find the direction and magnitude of the force that acts on the metallic block. (c) The area of the advancing front face of the block is essentially equal to ℓd. Considering the force on the block as acting on this face, find the stress (force per area) on it. (d) Express the energy density in the electric field between the charged plates in terms of Q₀, ℓ, d, and ϵ₀. (e) Explain how the answers to parts (c) and (d) compare with each other.

Figure P25.39

 

A capacitor is formed by two metal plates. The plates are squarewith width W on each side. The plates are separated by a distanced. A voltage V is applied across the two plates.

A dielectric is inserted between the two plates that extendsthrough the capacitance and occupies half of the volume between thetwo plates. The remaining volume between the plates is simply air.The relative dielectric constant of the material inserted is2.0.

a. Find the electric field intensity E and the electric fluxdensity D in each of the regions between the two plates.
b. Calculate the capacitance between the two plates.
c. Calculate the energy stored on the capacitor.
d. If the dielectric is removed so that only air remains betweenthe two plates, is the energy stored higher of lower than with thedielectric?

A capacitor is constructed from two square plates of sides l and separation d. Charges and are placed on the plates, and the power supply is then removed. A material of dielectric constant κ is inserted a distance x into the capacitor, as in Figure P25.49 (page 690). Assume d is much smaller than x.

a) Find the equivalent capacitance of the device.

b) Calculate the energy stored in the capacitor.

c) Find the direction and magnitude of the force exerted on the dielectric.

d) Obtain a numerical value of the force when , assuming that , , the dielectric is glass , and the capacitor was charged to before the dielectric was inserted.

Suggestion: The system can be considered as two capacitors connected in parallel.

A capacitor with a 3 mm gap has a potential difference of 6 volts (see the figure). A disk of glass 1.64 mm thick, with area the same as the area of the metal plates, has a dielectric constant of 1.9. It is inserted in the middle of the gap between the metal plates. Now what is the potential difference of the two metal disks? (It helps to make a diagram showing the electric field along a path.)