A point charge Q is located on the axis of a disc of radius R at a distance b from the plane of the disk. If one - fourth of the electric flux from the charge passes through the disk, then `R = sqrt(kb)`. Find k.

A point charge Q is located on the axis of a disc of radius R at a distance b from the plane of the disc (figure). Show that if one-fourth of the electric flux from the charge passes through the disc, then R=sqrt3b .

A point charge q is placed at a point on the axis of a non-conducting circular plate of radius r at a distance R(gt gtr) from its center. The electric flux associated with the plate is

A point charge Q is placed outside a hollow spherical conductor of radius R , at a distance r (r gt R) from its centre C . The field at C due to the induced charges on the conductor is

A positive point charge Q is placed (on the axis of disc) at a distance of 4 R . Above the centre of a disc of radius R as shown in situation I. the magnitude of electric flux through the disc is (phi) . Now a hemis pherical shell of radius R is placed over the disc. such that it forms a closed surface as shown in situation II. The flux through the curved suface in situation II taking direction of area vector along outward normal as positive is

A point charge Q is placed inside a conducting spherical shell of inner radius 3R and outer radius 5R at a distance R from the centre of the shell. The electric potential at the centre of the shell will be

A point charge q is placed at a distance d from the centre of a circular disc of radius R. Find electric flux flowing through the disc due to that charge

A point charge placed on the axis of a uniformly charged disc experiences a force f due to the disc. If the charge density on the disc sigma is, the electric flux through the disc, due to the point charge will be

A point charge q is located at the centre fo a thin ring of radius R with uniformly distributed charge -q , find the magnitude of the electric field strength vectro at the point lying on the axis of the ring at a distance x from its centre, if x gt gt R .

An infinite, uniformly charged sheet with surface charge density sigma cuts through a spherical Gaussian surface of radius R at a distance X from its center, as shown in the figure. The electric flux Phi through the Gaussian surface is .

A point charge q is placed at the origin . How does the electric field due to the charge very with distance r from the origin ?