`A+q_(1)` charge is at centre of an imaginary spherical Gaussion surface 'S', and `-q_(1)` charge is placed nearby this `+q_(1)` charge inside 'S'. A charge `+q_(2)` is located outside this Gaussian surface. Then electric field on Gaussian surface will be :

A closed surface is vacumm encloses charges -q and +3q . Another charge -2q lies outside the surface. Total electric flux over the surface is

Gauss's law and Coulomb's law , although expressed in different forms , are equivalent ways of describing the relation between charge and electric field in static conditions . Gauss's law is epsilon_(0) phi = q_(encl) ,when q(encl) is the net charge inside an imaginary closed surface called Gaussian surface. The two equations hold only when the net charge is in vaccum or air . If the charge q_(3) and q_(4) are displaced (always remaining outside the Gaussian surface), then consider the following two statements : A : Electric field at each point on the Gaussian surface will remain same . B : The value of oint vec(E ) .d vec(A) for the Gaussian surface will remain same.

A charge q is enclosed by an imaginary Gaussian surface. If radius of surface is increasing at a rate (dr)/(dt)= K , then