The electric field E is measured at a point P (0, 0, d) generated due to various charge distributions and the dependence of E on d is found to be different for different charge distributions. Column I contains different relations between E and d. Column II describes different electric charge distributions, along with their locations. Match the functions in Column I with the related charge distribution(s) in Column II.

The electric field is measured at a point 0,0, generated due to various charge distributions and the dependence of on is found to be different for different charge distributions. List-I contains different relations between E and . List-II describes different electric charge distributions, along with their locations. Match the functions in List-I with the related charge distributions in List-II.

Match the field lines given in Column I with charge configuration due to which field lines exist in Column II.

Column I represents a charged particle being thrown in different combinations of magnetic and electric field: Column II represents the path followed by the charged particle

In the electric field of a point chargde q , a cetrain charge is carried from point A to B, C, D and E . Then the work done

An irregular shaped non conductor has some charge distribution. The potential difference between the two points A and B in it is V. If it is now enveloped in an spherical non conducting shell having uniform charge distribution in it, the new potential difference between the points (neglect any induction due to presence of charge)

A charge q is uniformly distributed along an insulating straight wire of length 2l as shown in Fig. Find an expression for the electric potential at a point located a distance d from the distribution along its perpendicular bisector.

A charge +Q , is uniformaly distributed within a sphere of radius R. Find the electric field, due to this charge distribution, at a point distant r form the centre of the spehre where : (i) 0 lt r lt R and (ii) r gt R

Charge Q is distributed on two identical capacitors in parallel. Seperation of the plates in each capacitor is d_0 . If the first plate of the capacitor C_1 and the second late of the capacitor C_2 start moving to the left with constant speed v, then match the options of Column I with those in Column II Match the column I and Column II

In each situation of Column - I, two electric dipoles having dipole moments vec (p_(1)) and vec (p_(2)) of same magnitude ("that is" , p_(1) = p_(2)) are placed on x-axis symmertrically about origin in different orientations as shown. In column - II certain inferences are drawn for these two dipoles. Then match the different orientations of dipoles in column - I with the corresponding results in column - II. [In column I the co-ordinates corresponding to the centres of dipoles and dipoles having the same dipole lenght]

There is a solid sphere of radius R having uniformly distributed charge throughout it. What is the relation between electric field E and distance r from the centre (r is less than R) ?