Question

Consider a capacitor of capacitance \( C \), with plate area \( A \) and plate separation \( d \), filled with air [Fig. (a)]. The distance between the plates is increased to \( 2d \) and one of the plates is shifted as shown in Fig. (b). The capacitance of the new system now is:

• A. \( \frac{C}{4} \)
• B. \( \frac{C}{2} \)
• C. \( 2C \)
• D. \( 4C \)
• A. \( \frac{\sigma + \sigma_p}{\sigma} \)
• B. \( \frac{\sigma}{\sigma - \sigma_p} \)
• C. \( \frac{\sigma + \sigma_p}{\sigma_p} \)
• D. \( \frac{\sigma}{\sigma_p} \)
• A. \( \frac{1}{2} \epsilon_0 E^2 \)
• B. \( \epsilon_0 Q^2 E \)
• C. \( \frac{1}{2} \epsilon_0 E^2 V \)
• D. \( \epsilon_0 E Q V \)
• A. \( \frac{1}{6} \)
• B. \( \frac{1}{3} \)
• C. 3
• D. \( \frac{7}{3} \)
• A. \( \frac{K + 1}{2K} \)
• B. \( \frac{2K}{K + 1} \)
• C. \( \frac{K}{K - 1} \)
• D. \( \frac{K - 1}{K} \)

Answer 1

The Correct Option is A

In this problem, we have a parallel plate capacitor with a capacitance \( C \) when the plates are separated by a distance \( d \). The capacitance \( C \) of a parallel plate capacitor is given by the formula: \[ C = \frac{\epsilon_0 A}{d} \] where \( \epsilon_0 \) is the permittivity of free space, \( A \) is the area of the plates, and \( d \) is the distance between the plates. When the distance between the plates is increased from \( d \) to \( 2d \), the capacitance will decrease because capacitance is inversely proportional to the distance between the plates. However, one of the plates is shifted, which changes the effective area of the capacitor. The shift reduces the effective area of overlap between the plates. The capacitance can be expressed as: \[ C' = \frac{\epsilon_0 A'}{2d} \] where \( A' \) is the effective overlapping area, which is now reduced. In this case, due to the plate shift, the effective overlapping area is halved. Thus, the new capacitance is given by: \[ C' = \frac{C}{4} \] Therefore, the correct answer is \( \frac{C}{4} \).

Answer 2

In this problem, we are dealing with a parallel plate capacitor with a dielectric slab inserted between the plates. The charge density on the plates is \( \sigma \), and the dielectric slab has an induced charge density \( \sigma_p \) on its faces. The dielectric constant \( K \) is a measure of the change in the electric field due to the dielectric material. To find \( K \), we need to consider the following: 1. Capacitor without Dielectric: The electric field between the plates of the capacitor, when there is no dielectric, is given by: \[ E_0 = \frac{\sigma}{\epsilon_0} \] where \( \sigma \) is the charge density on the plates and \( \epsilon_0 \) is the permittivity of free space. 2. Capacitor with Dielectric: When a dielectric slab is inserted between the plates, the dielectric constant \( K \) modifies the electric field. The charge density on the plates is modified due to the presence of the dielectric, and the total effective charge density becomes \( \sigma + \sigma_p \), where \( \sigma_p \) is the induced charge density on the faces of the dielectric slab. 3. Dielectric Constant: The dielectric constant \( K \) relates the electric field with the dielectric to the electric field without the dielectric. It is given by the ratio of the total charge densities, considering the induced charges on the dielectric. The formula for the dielectric constant \( K \) is: \[ K = \frac{\sigma + \sigma_p}{\sigma} \] Thus, the dielectric constant is the ratio of the total charge density (sum of the charge density on the plates and the induced charge on the dielectric) to the original charge density on the plates. Therefore, the correct expression for the dielectric constant \( K \) is \( \frac{\sigma + \sigma_p}{\sigma} \).

Answer 3

To calculate the energy stored in a parallel plate capacitor, we can use the general formula for the energy stored in an electric field. The energy density \( u \) in the electric field is given by: \[ u = \frac{1}{2} \epsilon_0 E^2 \] where \( \epsilon_0 \) is the permittivity of free space and \( E \) is the electric field between the plates. The total energy stored in the capacitor is the energy density multiplied by the volume \( V \) of the region between the plates. The volume of the space between the plates is given by \( V = A \times d \), where \( A \) is the area of the plates and \( d \) is the distance between the plates. Thus, the total energy \( U \) stored in the capacitor is: \[ U = u \times V = \frac{1}{2} \epsilon_0 E^2 \times V \] Hence, the correct answer is \( \frac{1}{2} \epsilon_0 E^2 V \).

Answer 4

In this problem, we are dealing with capacitors in a complex network. Let us first simplify the network of capacitors: 1. Capacitance of N: The capacitor N has a capacitance of \( 2C \). 2. Capacitors A, B, and M: Each of these capacitors has a capacitance \( C \). Capacitors A and B are in series, and their equivalent capacitance can be found using the formula for series combination: \[ C_{AB} = \frac{C}{2} \] 3. Combination of A, B, and M: The combined capacitance of A and B, \( C_{AB} \), is in parallel with M. So, the total capacitance \( C_{\text{total}} \) of the network of A, B, and M is: \[ C_{\text{total}} = C_{AB} + C = \frac{C}{2} + C = \frac{3C}{2} \] 4. Final Combination with N: The final total capacitance \( C_{\text{final}} \) of the entire system is the combination of \( C_{\text{total}} \) and N (with capacitance \( 2C \)), which are in series: \[ C_{\text{final}} = \frac{C_{\text{total}} \times 2C}{C_{\text{total}} + 2C} = \frac{\frac{3C}{2} \times 2C}{\frac{3C}{2} + 2C} = \frac{3C^2}{\frac{7C}{2}} = \frac{6C}{7} \] 5. Charge Relationship: The total charge \( Q \) on the battery is related to the total capacitance and the battery voltage \( V \): \[ Q = C_{\text{final}} \times V = \frac{6C}{7} \times V \] The charge on capacitor N, denoted by \( Q' \), is the charge stored on the capacitor with capacitance \( 2C \), which is in parallel with the rest of the network. Since the voltage across N is the same as the battery voltage \( V \), the charge on N is: \[ Q' = 2C \times V \] 6. Ratio \( \frac{Q'}{Q} \): The ratio of the charges is: \[ \frac{Q'}{Q} = \frac{2C \times V}{\frac{6C}{7} \times V} = \frac{2C}{\frac{6C}{7}} = 7 \times \frac{2}{6} = \frac{7}{3} \] Thus, the correct answer is \( \frac{7}{3} \).

Answer 5

The capacitance \( C_0 \) of a parallel plate capacitor without any dielectric is given by the formula: \[ C_0 = \frac{\epsilon_0 A}{d} \] where \( \epsilon_0 \) is the permittivity of free space, \( A \) is the area of the plates, and \( d \) is the separation between the plates. When a dielectric slab of thickness \( \frac{d}{2} \) is inserted between the plates, the capacitance of the system changes. The dielectric constant of the material is \( K \), and the new capacitance \( C \) is affected by the dielectric. The insertion of the dielectric divides the capacitor into two regions: 1. A region with the dielectric, which contributes a capacitance of: \[ C_{\text{dielectric}} = \frac{K \epsilon_0 A}{\frac{d}{2}} = \frac{2K \epsilon_0 A}{d} \] 2. A region without the dielectric, which has the same capacitance as the original system: \[ C_{\text{no dielectric}} = \frac{\epsilon_0 A}{\frac{d}{2}} = \frac{2 \epsilon_0 A}{d} \] Thus, the total capacitance with the dielectric inserted, \( C \), is the sum of these two capacitances: \[ C = C_{\text{dielectric}} + C_{\text{no dielectric}} = \frac{2K \epsilon_0 A}{d} + \frac{2 \epsilon_0 A}{d} = \frac{2 \epsilon_0 A}{d} (K + 1) \] Now, the ratio of the capacitances is: \[ \frac{C}{C_0} = \frac{\frac{2 \epsilon_0 A}{d} (K + 1)}{\frac{\epsilon_0 A}{d}} = \frac{2(K + 1)}{1} = \frac{2K}{K + 1} \] Therefore, the correct answer is \( \frac{2K}{K + 1} \).