A thin, metallic spherical shell contains a charge Q on it. A point charge q is placed at the centre of the shell and another charge q₁ is placed outside it as shown in the figure. All the three charges are positive. The force on the central charge due to the shell is:

 

1. towards left

2. towards right

3. upward

4. zero

In the electric field of a point charge q, a certain charge is carried from point A to B, C, D, and E, the work done:

1. is least along the path AB

2. is least along the path AD

3. is zero along any one of the paths AB, AC and AE

4. is least along AE.

In a certain region of space, the electric field is zero. From this we can conclude that the electric potential in this region is:

1. constant

2. zero

3. positive

4. negative

An uncharged aluminium block has a cavity within it. The block is placed in a region permeated by a uniform electric field which is directed upwards. Which of the following is a correct statement describing conditions in the interior of the block's cavity?

1. The electric field in the cavity is directed upwards

2. The electric field in the cavity is directed downwards

3. There is no electric field in the cavity

4. The electric field in the cavity is of varying magnitude and is zero at the exact center.

A capacitor is filled with an insulator and a certain potential difference is applied to its plates. The energy stored in the capacitor is U. Now the capacitor is disconnected from the source and the insulator is pulled out of the capacitor. The work performed against the forces of the electric field in pulling out the insulator is 4U. Then dielectric constant of the insulator is:

1. 4

2. 8

3. 5

4. 3

An insulator plate is passed between the plates of a capacitor. Then current(outside the capacitor):

1. Always flows from A to B

2. Always flows from B to A

3. First flows from A to B and then from B to A

4. First flows from B to A and then from A to B

For a uniformly charged sphere with a positive charge distributed over its volume and having a radius \(R\), which location will the electric potential be maximum?
1. on the surface
2. at the centre
3. at a distance \(\frac{R}{2}\) from the surface
4. at a distance \(\frac{3R}{2}\) from the surface

A student charges a capacitor in such a manner that it stores energy of 1 J. Now he wants to increase the potential energy to 4 J. He should:

1. quadruple the potential difference across the capacitor without changing the charge

2. double the potential difference across the capacitor without changing the charge

3. double both the potential difference and charge

4. double the charge without changing the potential difference

An electron beam passes between two parallel plate electrodes as shown in the diagram. The bottom plate is kept at zero potential, while a slowly varying positive voltage is applied to the upper plate, as shown in the graph. After passing between the plates the beam hits a screen and makes spot. Ignoring gravity , the spot is:

1. deflected up

2. deflected down

3. deflected up then down

4. deflected down then up

A parallel plate capacitor is charged from a cell and then isolated from it. The separation between the plates is now increased.

1. the force of attraction between the plates will increased

2. the field in the region between the plates will not change

3. the energy stored in the capacitor will decrease

4. the potential difference between the plates will decrease