An unchanged conductor of inner radius `R_(1)` and outer radius `R_(2)` contains a point charge q placed at point P (not at the centre) as shown in figure? Find out the following:

(i) `V_(C)` (ii) `V_(A)` (iii) `V_(B)` (iv) `E_(A)` (v) `E_(B)`
(vi) force on charge Q if it is placed at B

An uncharged conductor of inner radius R_(1) and outer radius R_(2) constains a point charge q at the centre as shown in figure (i) Find vec(E) and V at points A, B and C (ii) If a pint charge Q is kept out side the sphere at a distance 'r' ( gt gt R_(2)) from centre then find out resultant force on charge Q and charge q.

Find the equivalent resistance of the network shown in the figure between the points A and B if (i) V_(A) gt V_(B) (ii) V_(A) lt V_(B)

Inside a conducting hollow sphere of inner radius R_(1) and outer radius R_(2) , a point charge q is placed at a distance x from the center as shown in (Fig. 3.70.) Find. . (i) electric potential at C (ii) electric field and potential at a distance r from the center outside the shell.

Inside a charged thin conducting shell of radius R, a point charge +Q is placed as shown in figure potential of shell may be

Find out following (i) V_(A)-V_(B) (ii) V_(B)-V_(C) (iii) V_(C)-V_(A) (iv) V_(D)-V_(C) (v) V_(A)-V_(D) (vi) Arrange the order of potential for points A, B, C and D.

Shown in the figure is a shell made of a conductor. It has inner radius a and outer radius b, and carries charge. Q at its centre is a dipole vecp shown in this case: