A cylinder space of radius R is filled with a unifrom magnetic induction a parallel to the axis of the space . If B change at the rate .Find the electric field at a distance (i) `rlt R` (ii) `rgt R`

A cylindrical space of radius R is filled with a uniform magnetic induction parallel to the axis of the cylinder. If B charges at a constant rate, the graph showin the variation of induced electric field with distance r from the axis of cylinder is

A cylinder of radius r and length l is placed in an uniform electric field parallel to the axis of the cylinder. The total flux for the surface of the cylinder is given by-

A cylinder of radius R and length l is placed in a uniform electric field E parallel to the axis of the cylinder. The total flux over the curved surface of the cylinder is

A cylinder of radius R and length L is placed in a uniform electric field E parallel to the axis. The total flux for the surface of the cylinder is given by

A cylinder of radius R and length L is placed in the uniform electric field E parallel to the cylinder axis.The total flux from the two flat surface of the cylinder is given by

There is a long cylinder of radius R having a cylindrical cavity of radius R//2 as shown in the figure. Apart from the cavity, the entire space inside the cylinder has a uniform mag- netic field parallel to the axis of the cylinder. The magnetic field starts changing at a uniform rate of (dB)/(dt) = kT//s . Find the induced electric field at a point inside the cavity.

The electric flux through a hemispherical surface of radius R placed in a uniform electric field E parallel to the axis of the circular plane is

A uniform magnetic field exists in a circular region of radius R centrad at O. The field is perpendicular to the plane of paper and is strength varies with time as B=B_(0)t . Find the induced electric field at a distance r from the centre for (i) r lt R , (ii) r gt R . Also, plot a graph between |E| and r for both the cases.