Gauss's theorem is

State Gauss's theorem in electrostatiics. State the expression for electric field intensity at a point outside an infinitely long charged conducting cylinder.

Statement-1. The number of electric lins of force emanting from 1 mu C charge in vacumm is 1.13xx10^(6) . Statement-2. This follows from Gauss's theorem in electrostatics.

A physics teacher explains Gauss's theorem in electrostatics and Gauss's theorem in magnetism to his students in a class. He tells them that total normal electric flux over a closed surface in vacuum is phi_e=(Q)/(in_0) , where Q is algebraic sum of charges inside the surface. Further, total normal magnetic flux over a closed surface in vacuum is always zero. The teacher emphasises that this is because in magnetism, poles always exist in unlike pairs of equal strengh, i.e., isolated magnetic poles called monopoles do not exist. Read the above passage and answer the following questions: (i) What are the implications of Gauss's theorem in magnetism in day to day life? (ii) Two magnetic dipoles of moments 5Am^2 and 3Am^2 oriented along opposite directions are enclosed in a surface. What is total normal magnetic flux over this surface? (iii) Two point charges +4q and -q are enclosed in a surface in vacuum, and third charge 5q lies outside the surface. What is total normal electric flux over the surface?

State Gauss's Theorem in electrostatics and deduce coulomb's law from Gauss's theorem.

The application of Gauss's theorem gives rise to an easy evolution of electric field in the case of

A : Gauss theorem is applicable on any closed surface. R : In order to find the value of electric field due to a charge distribution, Gauss' theorem should be applid on a symmetrical closed surface.

Statement-1 : Gauss theorem is not applicable in magnetism. Statement-2 : Mono magnetic pole does not exist.