The electric flux through a Gaussian surface that encloses three charges given by `q_(1) = -14nC, q_(2) = 78.85 nC, q_(3)= -56nC`

In the given figure, there are four point charges placed at the vertices of a square of side, a=1.4 m . If q_(1)=+18 nC,q_(2)=-24 nC,q_(3)+35nC and q_(4)=+16 nC m then find the electric at the centre P of the square Assume the potential to be zero at infinity.

The three small spheres as shown in figure carry charges q_1 = 4nC, q_2 = -7.8nC and q_3 = 2.4nC . Find the net electic flux through each of the following closed surfaces shown in cross section in the figure. a. S_1 b. S_2 c. S_3 d. S_4 e. S_5 . Do your answers to parts from (a) to (e) depend on how the charge is distributed over each small sphere? Why or why not? .

Consider a Gaussian spherical surface covering a dipole of charge q and -q, then

Three concentric metallic spherical shells of radii R, 2R, 3R are given charges Q_(1) Q_(2) Q_(3) , respectively. It is found that the surface charge densities on the outer surface of the shells are equal. Then, the ratio of the charges given to the shells Q_(1) : Q_(2) : Q_(3) 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.

The graph of current versus time in a wire is given by If charge that flows through a wire in 7.5 s is q_(1) and that flows thorugh the wire in 15s is q_(2) , then ratio q_(1):q_(2) is

The electric force on a charge q_1 due to q_2 is (4hati-3hatj)N . What is the force on q_2 due to q_1

A Gaussian surface S encloses two charges q_(1)= q and q_(2) = -q the field at p is where vecE_(1), vecE_(2)and vecE_(3) are the field contributed by q_(1),q_(2)and q_(3)at P respectively.

The electric field at (30, 30) cm due to a charge of -8nC at the origin in NC^(-1) is

Three charges are placed at the vertices of an equilateral triangle of side 10 cm. Assume q_(1)=1 muC,q_(2)=-2 muC and q_(3)=4 muC . Work done in separating the charges to infinity is