The electric field within the nucleus is generally observed to be linearly dependent on r. This implies.

The nuclear charge ( Ze ) is non uniformlly distribute with in a nucleus of radius r. The charge densilty rho(r) (charge per unit volume) is dependent only on the radial distance r form the centre of the nucleus s shown in figure. The electric field is only along the radial direction. The electric field within the nucleus is generaly observed to be linearly dependent on r. This implies

The electric field at r= R is

In the following question a statement of assertion (A) is followed by a statement of reason (R ) A: the potential difference between two concentric sphereical shells depends only on the charge of inner shell R : the electric field in the region in between two shells depedns on the charge of inner shell and electric field is the negative of potential gradient.

If the total charge enclosed by a surface is zero, does it imply that the electric field everywhere on the surface is zero ? Conversely, if the electric field everywhere on a surface is zero, does it imply that net charge inside is zero.

Assertion : Current flows in a conductor only when there is an external electric field within the conductor. Reason: The drift velocity of the electrons is directly proportional to the electric field.

The acceleration of the charge on the gap faces will cease when the total electric field within the ring becomes zero. For this to happen, the electric field E_(0) in the gap is

Consider the following two statements regarding a linearly polarized, plane electromagnetic wave: The electric field and the magnetic field have equal average values. The electric energy and the magnetic energy have equal average values.

The electric field at 2R from the centre of a uniformly charged non - conducting sphere of rarius R is E. The electric field at a distance ( R )/(2) from the centre will be

Determine the electric field strength vector if the potential of this field depends on X, coordinates as V = 10 axy

Determine the electric field strength vector if the potential of this field depends on x, coordinates as (a) V = a (x^2 — y^2) (b) V = axy where, a is a constant.