The magnitude of electric field intensity at point `B (2 , 0, 0)` due to a dipole of dipole moment `vec(P) = hati + sqrt(3)hatj` kept at origin is (assum that the point B is at a large distance from the dipole end `K = 1/(4 pi epsilon_0)`)

The magnitude of electric field intensity at point B(2,0,0) due to dipole of dipole moment, vec(p)=hat(i)+sqrt(3)hat(j) kept at origin is (assume that the point B is at large distance from the dipole and k=(1)/(4pi epsilon_(0)))

The magnitude of electric field intensity at point B(x,0,0) due to a dipole of dipole moment , vec(P) - P_(0) ( hat(i) + sqrt(3)hat(j)) kept at origin is sqrt(n) ((kp_(0))/(r^(3))) , find n (assume that the point is at large distance form the diople , k = (1)/(4 pi in_(0)) .

The electric field intensity vec(E) , , due to an electric dipole of dipole moment vec(p) , at a point on the equatorial line is :

Find out electric field intensity at point A (0, 1m, 2m) due to a point charge -20 muC situated at point B (sqrt(2)m, 0, 1m) .

Electric potential due to a dipole at a position vec r from its centre is: where (K = 1/(4pi epsilon_0)

A dipole of dipole moment P is kept at the centre of a ring of radius R and charge Q. If the dipole lies along the axis of the ring. Electric force on the ring due to the dipole is : (K = (1)/(4pi epsilon_(0)))

Electric dipole of moment vecp = phati is kept at a point (x,y) in an electric field vecE = 4xy^2hati + 4x^2yhatj . Find the force on the dipole.

The magnitude of magentic field , due to a dipole of magnetic moment 2.4 Am^(2) , at a point 200 cm away from it in the direction making an equal of 90^(@) with the dipole axis is

Electric field intensity at a point B due to a point charge Q kept at point A is 24 NC^(-1) , and electric potential at B due to the same charge is 12 JC^(-1) . Calculate the distance AB and magnitude of charge.

Electric field intensity (E) due to an electric dipole varies with distance (r ) from the point of the center of dipole as :