The variation of potential with distance R from the fixed point is shown in (Fig. 3.125).
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The electric field at `R = 5 m` is.

The electric field at r= R is

The variation of potential with distance R from a fixed point is shown in figure. The electric field at R = 5 m is -

The variation of potential with distance r from a fixed point is shown in fig. The electric field at r = 5cm, is :

The variation of potential with distance x from a fixed point is shown in figure. Find the magnitude of the electric field (in V // m) at x=13 m .

The variation of potential with distance R from a fixed point is as shown below. A charge - q is put at R = 3 m and released. The charge will

Variation of electrostatic potential along the x - direction is shown in (Fig. 3.142). The correct statement about electric field is .

The nuclear charge ( Ze ) is non uniformlly distribute with in a nucleus of radius r. The charge density 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 at r=R is

The variation of electric potential for an electric field directed parallel to the x - axis is shown in (Fig. 3.110). Draw the variation of electric field strength with the x- axis. .

Inside a conducting hollow sphere of inner radius R_(1) and outer radius R_(2) , a point charge q is placed at a distance x from the center as shown in fig. Find. . (i) electric potential at C (ii) electric field and potential at a distance r from the center outside the shell.

An uncharged metallic solid sphere of radius R is placed at a distance 2R from point charge Q as shown in figure. The electric field intensity due to induced charge at centre of sphere is