Solving Electric Field & Potential of Infinitely Long Rod

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SUMMARY

The discussion focuses on solving the electric field and potential of an infinitely long rod with a uniform volume charge density ρ. Using Gauss' Law, the electric field inside the rod is established as E = ρr/2ε₀, indicating that it points radially outward. For the potential difference calculation, the formula V = -∫₀ᴿ E · dr is utilized, emphasizing the need to apply cylindrical coordinates for the integration process. The challenge lies in correctly setting up the integral to find the potential difference between the rod's surface and its axis.

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The problem:

An infinitely long rod of radius R carries a uniform volume charge
density ρ (ρ > 0).

(a) Show how to use Gauss' Law to prove that the
electric field inside this rod points radially
outward and has magnitude:

E = \rho r/2\epsilon_0

(b) Integrate the electric field over an appropriate
displacement to find the potential difference from
the rod's surface to its axis. State explicitly
which of those two locations is at the higher
potential.


My answer:

I solved for part (a) using a Gaussian surface symmetry and got this as my final answer.

E(2 \pi rL) = \rho r/2 \epsilon_0
E = \rho r/2\epsilon_0

I am having a hard time starting part (b). I am not sure where to start.
 
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Electric potencial is a path integral of electric intensity from point A to point B
 
More specifically the formula is V = -\int^0_{R} \mathbf{E} \cdot d\mathbf{r}. In this case since you've derived the expression in cylindrical coordinates you might as well make use of cylindrical basis vectors for the line integral. Just substitute all the values into the integration, find the dot product and integrate.
 

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