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

The electric charges are distributed in a small volume. The flux of the electric field through a spherica surface of radius 10 cm surrounding the total charge is 20 V - m . The flux over a concentric sphere of radius 20 cm will be

The electric field in a region of space is given by, vec(E ) = E_(0) hat(i) + 2 E_(0) hat(j) where E_(0)= 100N//C . The flux of this field through a circular surface of radius 0.02m parallel to the Y-Z plane is nearly.

Electric charge are distributed in a small volume. The flux of the electric field through a spherical surface of radius 10cm surrounding the total charge is 25 V m. The flux over a concentric sphere of radius 20 cm will be

If the flux of the electric field through a closed surface is zero,

Find the electric flux due to a point charge 'Q' through the circular region of radius R if the charge is placed on the axis of ring at a distance x.

A time varying uniform magnetic field passes through a circular region of radius R. The magnetic field is directed outwards and it is a function of radial distance 'r' and time 't' according to relation B-B_(0)rt. The induced electric field strength at a radial distance R//2 from the centre will be.

There is a uniform magnetic field B in a circular region of radius R as shown in Fig. 3.149 whose magnitude changes at the rate of dB//dt . The emf circular concentric conducting arc of radius R_(1) having an angle theta as shown (-OAO' = theta) is

There is a uniform magnetic field B in a circular region of radius R as shown in Fig. 3.149 whose magnitude changes at the rate of dB//dt . The emf circular concentric conducting arc of radius R_(1) having an angle theta as shown (-OAO' = theta) is

A graph of the x-component of the electric field as a function of x in a region of space is shown in the figure. They y and z-components of the electric field are zero in this region. The electric potential at the origin is 10 V. The value of x for which potential is zero 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 :