A dipole is placed at origin of corrdinate system as shown in figure, find the electric field at point P (0, y) .

A cube has sides of length L=0.2 m It is placed with one corner at the origin as shown in figure The electric field in uniform and given by vec(E)=(2.5hat(i)-4.2hat(j))N//C .Find the electric flux through the entire cube.

A wire loop ABCDE carrying a current I is placed in the x-y plane as shown in the figure. A particle of mass m and charge q is projected from origin with velocity vec(V) = (V_(0))/(sqrt(2))(hat(i) + hat(j)) m//sec . (a) Find the instaneous acceleration (b) If an external magnetic field vec(B) = B_(0) hat(i) is applied, find the force and torque acting on the loop due to this field.

An electric dipole of ( 100 hat(k) pC-m is located at origin. Determine the field and potential at point P ( 1m , (pi)/(3) , (pi)/(2)) in spherical coordinate system p ( r , theta, phi)

Electrostatic force experienced by - 3 mu C charge placed at point 'P' due to a system 'S' of fixed point charges as shown in figure is vec(F) = (21 hat(i) + 9hat(j))mu N . Find out electric field intensity at point P due to S.

Column I gives a situation in which two dipoles of dipole moment p hat(i) and sqrt(3)phat(j) are placed at origin. A circle of radius R with centre at origin is drawn as shown in figure. Column II gives coordinates of certain positions on the circle. Match the statements in Column I with the statements in Column II.

An electric field is given by vec(E )=(yhat(i)+hat(j))NC^(-1) . Find the work done (in j) by the electric field in moving a 1 C charge form vecr_(A)=(2 hat(i)+2 hat(j))m to vecr_(B)=(4 hat(i)+hat(j))m .