If \(50~\text{J}\) of work must be done to move an electric charge of \(2~\text{C}\) from a point where the potential is \(-10\) volts to another point where the potential is \(\mathrm{V}\) volts, then the value of \(\mathrm{V}\) is:
1. \(5\) volts
2. \(-15\) volts
3. \(+15\) volts
4. \(+10\) volts
Three capacitors \(A\), \(B\) and \(C\) are connected in a circuit as shown in Fig. What is the charge in \(\mu \text{C}\) on the capacitor \(B\):
1. | \(\frac{1}{3}\) | 2. | \(\frac{2}{3}\) |
3. | \(1\) | 4. | \(\frac{4}{3}\) |
1. | \(V = -x+y+\) constant |
2. | \(V\) = constant |
3. | \(V=-\left({x}^2+{y}^2\right)+\) constant |
4. | \(V=-x y+\) constant |
What is the area of the plates of a \(2~\text{F}\) parallel plate capacitor, given that the separation between the plates is \(0.5~\text{cm}\)?
1. \(1100~\text{km}^2\)
2. \(1130~\text{km}^2\)
3. \(1110~\text{km}^2\)
4. \(1105~\text{km}^2\)
1. | \(-23.1\) eV | 2. | \(27.0\) eV |
3. | \(-27.2\) eV | 4. | \(23.7\) eV |
1. | can not be defined as \(-\int_{A}^{B} { \vec E\cdot \vec{dl}}\) |
2. | must be defined as \(-\int_{A}^{B} {\vec E\cdot \vec{dl}}\) |
3. | is zero |
4. | can have a non-zero value. |
a. | the electric field is uniform |
b. | the electric field is zero |
c. | there can be no charge inside the region |
d. | the electric field shall necessarily change if a charge is placed outside the region |
Choose the correct statement(s):
1. (b) and (c)
2. (a) and (c)
3. (b) and (d)
4. (c) and (d)
In the circuit shown in the figure initially key \(K_1\) is closed and key \(K_2\) is open. Then \(K_1\) is opened and \(K_2\) is closed (order is important).
[Take \(Q_1\) and \(Q_2\) as charges on \(C_1\) and \(C_2\) and \(V_1\) and \(V_2\) as voltage respectively.]
Then,
a. | charge on \(C\) gets redistributed such that \(V_1= V_2\) |
b. | charge on \(C\) gets redistributed such that \(Q_1= Q_2\) |
c. | charge on \(C\) gets redistributed such that \(C_1V_1+C_2V_2 = C_1 E\) |
d. | charge on \(C\) gets redistributed such that \(Q_1+Q_2 =Q\) |
A parallel plate capacitor is connected to a battery as shown in the figure. Consider two situations.
A: | Key \(K\) is kept closed and plates of capacitors are moved apart using the insulating handle. |
B: | Key \(K\) is opened and plates of capacitors are moved apart using the insulating handle. |
a. | In A, \(Q\) remains the same but \(C\) changes. |
b. | In B, \(V\) remains the same but \(C\) changes. |
c. | In A, \(V\) remains the same and hence \(Q\) changes. |
d. | In B, \(Q\) remains the same and hence \(V\) changes. |
1. | (a) and (b) | 2. | (a) and (d) |
3. | (b) and (c) | 4. | (c) and (d) |
Equipotential at a great distance from a collection of charges whose total sum is not zero are approximately:
1. | spheres | 2. | planes |
3. | paraboloids | 4. | ellipsoids |