The potential of the electric field produced by point charge at any point (x, y, z) is given by `V = 3x^(2) + 5` , where x ,y are in are in metres and V is in volts. The intensity of the electric field at (-2,1,0) is :

The electrostatic potential V at any point (x, y, z) in space is given by V=4x^(2)

An electric dipole is kept in the electric field produced by a point charge

The electirc potential at a point (x, y, z) is given by V = -x^(2)y - xz^(3) + 4 The electric field vecE at that point is

The electirc potential at a point (x, y, z) is given by V = -x^(2)y - xz^(3) + 4 The electric field vecE at that point is

The electirc potential at a point (x, y, z) is given by V = -x^(2)y - xz^(3) + 4 The electric field vecE at that point is

The electric potential at any point x,y and z in metres is given by V = 3x^(2) . The electric field at a point (2,0,1) is

(A)Two point charges q_1 and q_2 are kept r distance apart in a uniform external electric field vecE . Find the amount of work done in assembling this system of charges. (B) A cube of side 20 cm is kept in a region as shown in the figure. An electric field vecE exists in the region such that the potential at a point is given by V = 10x + 5 , where V is in volt and x is in m. Find the electric field vecE and (ii) total electric flux through the cube.

In a certain region of space, variation of potential with distance from origin as we move along x-axis is given by V = 8 x^(2) + 2 , where x is the x-coordinate of a point in space. The magnitude of electric field at a point ( -4,0) is

In a certain region of space, variation of potential with distance from origin as we move along x-axis is given by V = 8 x^(2) + 2 , where x is the x-coordinate of a point in space. The magnitude of electric field at a point ( -4,0) is

The potential at any point is given by V = x(y^2 - 4 x^2) . Calculate the cartesian components of the electric field at the point.