When we use Gauss theorem/ gauss law….how do you decide what shape the Gaussian surface chosen must be for a given charge distribution(finite charge distribution)….because for a given charge distribution,I can draw a sphere , a cylinder , a cube and similarly any Gaussian surface enclosing the charge completely…but all of them would give different values of electric field right at the same given point.please explain how the same universal law giving different expressions of electric field at the same point due to a finite charge distribution makes any sense…because irrespective of shape considered,the same net charge is enclosed
[Physics] Gauss law ambiguity
electric-fieldselectrostaticsgauss-law
Best Answer
Let me state Gauss law very briefly:
The surface integral of electric field over a closed surface is equal to the charge contained within the surface over $\epsilon_0$. $$ \int_{\Delta s}{\mathbf{E\cdot ds}} = \frac{q_{en}}{\epsilon_0} $$ $$or$$ The divergence of Electric field at a point of space is equal to the charge density at that point over $\epsilon_0$. $$\nabla\cdot\mathbf{E} = \frac{\rho}{\epsilon_0}$$
Unlike Coulomb's law, which directly gives an expression for the electric field, Gauss law gives a differential equation of vectors to solve the electric field from. In short, electric field is difficult to calculate from Gauss law in most circumstances.
But we still can find the electric field if we somehow solve the integral. This is practical when there exists symmetry in the situation where we want to calculate electric field.
So,
If you take an arbitrary gaussian surface, chances are that it is not very symmetrical and you are not able to calculate the integral on the left side of the equation. Once you know the electric field, and you now calculate the integral, you'll see that Gauss law holds. So, although you have an infinite number of choices of surfaces to verify Gauss law, you don't have as many to find the electric field from.
Let me stress again that this simply isn't true. If you are able to find the electric field from one of the surfaces, and you plug that value value of electric field in Gauss law for any arbitrary surface, then you will always find that Gauss law holds good.
Take home message: You may take a closed surface of any shape as a gaussian surface and apply Gauss law, and there will be no inconsistency.
Hope it makes sense. :)