A negative charge released from a point A moves along the line AB. The potential at A is 15 V, and it varies uniformly along AB. The potential at B.

Write an equation for potential at a point in a uniformly charged spherical shell.

The work done to move a charge along equipotential from A to B

A particle having mass 1 g and electric charge 10^(-8) C travels from a point A having electric potential 600 V to the point B having zero potential. What would be the change in its kinetic energy ?

Figures 2.8 (a) and (b) show the field lines of a positive and negative point charge respectively. (a) Give the signs of the potential difference V_(P)-V_(Q): V_(B)-V_(A) . (b) Give the sign of the potential energy difference of a small negative charge between the points Q and P, A and B. (c) Give the sign of the work done by the field in moving a small positive charge from Q to P. (d) Give the sign of the work done by the external agency in moving a small negative charge from B to A. (e) Does the kinetic energy of a small negative charge increase or decrease in going from B to A?

Calculate potential on the axis of a ring due to charge Q uniformly distributed along the ring of radius R.

2C electric charge Is displaced from a point of electric potential -20 V to some other point. The work done is 200 J, then electric potential of second point V_(2) = ........ volt.

A positively charged particle is released from rest in an unform electric field. The electric potential energy of the charge

Two charges 2 C and 3 C are located 100 m apart. At what point on the line joining the two charges is the electric potential zero ? Take the potential at infinity to be zero. .

Two fixed, equal, positive charges, each of magnitude 5xx10^-5 coul are located at points A and B separated by a distance of 6m. An equal and opposite charge moves towards them along the line COD, the perpendicular bisector of the line AB. The moving charge, when it reaches the point C at a distance of 4m from O, has a kinetic energy of 4 joules. Calculate the distance of the farthest point D which the negative charge will reach before returning towards C.

A charge Q is uniformly distributed over a long rod AB of length L as shown in the figure. The electric potential at the point O lying at distance L from the end A is