The variation of potential with distance x from a fixed point is shown in figure. Find the magnitude of the electric field (in V`//`m) at `x=13 m`.

The variation of potential with distance r from a fixed point is shown in fig. The electric field at r = 5cm, is :

Draw a graph for variation of potential V with distance r for a point charge Q.

A dipole is placed at origin of coordinate system as shown in figure, find the electric field at point P (0, y) .

A point charge Q is placed at the centre of a spherical conducting shell. A total charge of -q is placed on the shell. The magnitude of the electric field at point P_1 at a distance R_1 from the centre is X. The magnitude of the electric field due to induced charges at point P_2 a distance R_2 from the centre is Y. The values of X and Y are respectively.

If V=-5x+3y+sqrt(15)z then find magnitude of electric field at point (a, y, z).

A V - X graph for an electric field in X-direction is shown in the figure. In which region is the magnitude of electric field maximum ? (a) A (b) B (c) C (d) D

A graph of the x-component of the electric field as a function of x in a region of space is shown in figure. The y- and z-components of the electric field are zero in this region. If the electric potential is 10 V at the origin, then the potential at x = 2.0 m is

A short electric dipole is situated at the origin of coordinate axis with its axis along x-axis and equator along y-axis. It is found that the magnitudes of the electric intensity and electric potential due to the dipole are equal at a point distance r=sqrt(5) m from origin. Find the position vector of the point in first quadrant.

Three solid sphere of mass M and radius R are placed in contact as shown in figure. Find the potential energy of the system ?

A particle is moving in a circle of radius r with speed v as shown in the figure. The magnitude of change in velocity in moving from P to Q is