The magnetic field within cylindrical region whose cross - section is indicated starts increasing at a constant rate `alpha` tesla/sec . The graph showing the variation of induced field with distance r from the axis of cylinder is :

The magnetic field at all points within the cyllindrical region whose cross section is indicated in the accompanying Figure starts increasing at a constant rate alpha . T//s . find the magnitud of electric field as a function of r , the distance from the geometric centre of the region.

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 uniform magentic field of induction B is confined in a cyclinderical region of radius R . If the field is incresing at a constant rate of (dB)/(dt)= alpha T//s , then the intensity of the electric field induced at point P , distant r from the axis as shown in the figure is proportional to :

The magnetic field within a long, straight solenoid with a circular cross - section of radius r is (as shown) increasing at a rate of alpha . The rate of change of flux through a circle with radius a inside the solenoid and with centre on the solenoid axis is

A uniform but time-varying magnetic field B(t) exists in a circular region of radius a and is directed into the plane of the paper, as shown. The magnitude of the induced electric field at point P at a distance r from the centre of the circular region

Which one of the following graphs shows the variation of magnetic induction B which distance r from a long wire carrying a current ?

A uniform but time varying magnetic field B(t) exist in a circular region of radius a and is directed into the plane of the paper as shown. The magnitude of the induced electric field at point P at a distance r form the centre of the circular region.

The magnetic field in the cylindrical region shown in figure increase at a constant rate of 20mT//sec . Each side of the square loop ABCD has a length of 1 cm and resistance of 4Omega . Find the current in the wire AB if the switch S is closed

The magnetic field in a certain cylindrical region is changing with time according to the law B=[16-4t^(2)] Tesla . The magnitude of induced electric field at point P at time t= time =2 sec , is

A uniform but time varying magnetic field is present in a circular region of radius R. The magnetic field is perpendicular and into the plane of the loop and the magnitude of field is increasing at a constant rate alpha . There is a straight conducting rod of length 2R placed as shown in figure. The magnitude of induced emf across the rod is