In a figure shown the electric field intenisity at `r=1,r=6m,r=9m` and `Vm^(-1)` is

The electric field at r= R is

In an electric field shown in figure, three equipotential figure, three equipotential surfaces are shown. If function are shown. If function of electric field is E=2x^2Vm^(-1) , and given that V_1 - V_2 = V_2-V_3 , then we have

For spherical charge distribution gives as . {{:(,rho = rho_(0)(1-(r)/(3)),"when" r le 3m),(,rho = 0 ,"when" r gt 3m):} ( where x is the distance form the centre of spherical charge distribution) The electric field intensity is maximum for the value of r=_______m.

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

A time varying magnetic field B=krt (where k is a constant r is the radial distance from centre O) is existing in a circular region of radius R as shown. If induced electric field at r=(R)/(2) is E_(1) and at r=2R is E_(2) then the ratio (E_(2))/(E_(1)) 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 potential with distance r from a fixed point is shown in fig. The electric field at r = 5cm, is :

Two concentric spherical shells of masses and radii m_(1), r_(1) and m_(2), r_(2) respectively are as shown. The gravitational field intensity at point P is

A spherical cavity of radius r is made in a conducting sphere of radius 2r. A charge 9 is kept at the centre of cavity as shown in the figure. Find the magnitude of the total electric field at(4r 0). у r (0 0) х 9 2r