Figure shows the electric lines of force emerging from a charged body. If the electric field at A and B are `E_A` and `E_B` respectively and if the displacement between A and B is r then

Figure shows some equipotential lines distributed in space . A charged object is moved from point A to point B .

Show that electric intensity at a point outside a charged cylinder is given by , E = (sigma R)/(in_0 kr)

When electric field intensity vec E at any point in the electric field is directed towards or away from the same fixed point then the field is

S = A(1-e^(Bxt)) , where S is speed and x is displacement. The units of B is

Show that electric intensity at a point outside a charged sphere is given by, E = (sigma R^2)/(in_0 kr^2)

A toy car with charge moves on a frictionless horizontal plane surface under the influence of a uniform electric field vec E . Due to the force qvec E E. its velocity increases from 0 to 6 m/s in one second duration. At that instant the direction of the field is reversed. The car continues to move for two more seconds under the influence of this field. The average velocity and the average speed of the day car between 0 to 3 seconds are respectively

The scalar product of electric field intensity and area vector through which the line of force emerges is _________

Intensity of an electric field E due to a dipole, depends on distance 'r' as