In the figure a hemispherical bowl of bowl of radius R is shown Electric field of intensity E is present perpendicular to the circular cross section of the hemisohere.

A hemispherical surface of radius R is kept in a uniform electric field E as shown in figure. The flux through the curved surface is

An isolated solid metal sphere of radius R is given an electric charge. The variation of the intensity of the electric field with the distance r from the centre of the sphere is best shown by

A ring of mass m and radius R rests in equilibrium on a smooth cone of semi-vertical angle 45^(@) as shown. The radius of the cone is 2R. the radius of circular cross section of the ring is r(r lt lt R) . What will be the tension in the ring?

Shown in the figure is a circular loop of radius, r and resistance R. A variable magnetic field of induction B=e^(-t) is established inside the coil. If the key (K) is closed at t=0 , the electrical power developed at the instant is equal to

A small solid sphere of mass m and radius r starting from rest from the rim of a fixed hemispherical bowl of radius R(gt gtr) rolls inside it without sliding. The normal reaction exerted by the sphere on the hemisphere when it reaches the bottom of hemisphere is

Calculate the gravitational field intensity and potential at the centre of the base of a solid hemisphere of mass m , radius R

Electric field intensity (E) due to an electric dipole varies with distance (r ) from the point of the center of dipole as :

A hemispherical cavity of radius R is created in a solid sphere of radius 2R as shown in the figure . They y -coordinate of the centre of mass of the remaining sphere is

The flux of electric field through the circular region of radius r as shown in the figure is

A small ball is pushed from a height h along a smooth hemispherical bowl of radius R. With what speed should the ball be pushed so that it just reaches the top of the opposite end of the bowl?