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$Q$ is evenly distributed over the volume of a ball of radius $a$ so that the space charge density is proportional to the distance $r$ from the center of the ball. Ie $ρ_v = kr$ where $k$ is a constant. I'm supposed to show that $p_v=kr$

attempt

$$\int E\cdot dA=\int \frac{Q}{4\pi r^2\epsilon_0}\cdot 4\pi r^2=\frac{Q}{\epsilon_0}$$

This is where i'm stuck. Should I use spherical coordinates and just

$$\int \frac{Q}{\epsilon_0}d\tau$$ or $$\iiint \frac{Q}{\epsilon_0}\cdot \rho^2 \sin\phi \, d\rho \, d\theta \, d\phi \, ?$$

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  • $\begingroup$ What other information do you have? It seems like you don't have enough $\endgroup$
    – Triatticus
    Commented Sep 10, 2018 at 16:14
  • $\begingroup$ @Triatticus That's the only information i'm given, besides that we have a Total charge $Q$ and i'm supposed to find the electrical field $E$ everywhere when ....$Q$ is evenly etc.... $\endgroup$
    – Undergrad2019
    Commented Sep 10, 2018 at 16:25
  • $\begingroup$ For charge densities in 1-, 2- , 3-dimensions we usually have the terms linear, surface, volume charge density and the symbols $\;\lambda, \sigma, \rho \;$ respectively. In your question you have $\;\rho=\text{constant} \;$ or $\;\rho(r)=\text{constant}\cdot r \;$ ??? $\endgroup$
    – Voulkos
    Commented Sep 10, 2018 at 17:15

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Edit: see comments below, there appears to be a misunderstanding of the question set - I shall update this answer to better reflect what OP actually asked when I get the chance later

(I'm not sure what you mean by "space charge density", but I'm assuming you want the $\mathbf{E}$ field as you say in your comment).

You need to use Gauss' law, which is $$\int\int\mathbf{E}\cdot\text{d}\mathbf{S} = \frac{Q_\text{enc}}{\epsilon_0}$$ The easiest way is to exploit the symmetry of the situation and consider a "test sphere" of arbitrary radius $r$, through which $\mathbf{E}$ field lines are passing through perpendicularly. The flux through this test sphere (which is the left hand-side of Gauss' law) is $$\int\int\mathbf{E}\cdot\text{d}\mathbf{S} =|\mathbf{E}|\int\int\text{d}S = A_\text{sphere}|\mathbf{E}|= 4\pi r^2|\mathbf{E}|$$ Where the first step above is true, because the electric field lines are alway parallel to the normal of your test surface sphere.

$Q_\text{enc}$is the charge enclosed in our test sphere, which is $\frac{4}{3}\pi r^3\rho$, where $\rho$ is the constant charge density. From that, you find that the electric field strength is indeed proportional to $r$ (at least inside the sphere).

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  • $\begingroup$ if i were to find the electric field of it knowing that the radius is proportional. $\endgroup$
    – Undergrad2019
    Commented Sep 11, 2018 at 21:12
  • $\begingroup$ would it be $E=\frac{\frac{4}{3}\pi r^3 \rho}{\epsilon 4\pi r^2}$ $\endgroup$
    – Undergrad2019
    Commented Sep 11, 2018 at 21:14
  • $\begingroup$ $E=\frac{r\rho}{3\epsilon}=>E=\frac{r^2k}{3\epsilon}$? $\endgroup$
    – Undergrad2019
    Commented Sep 11, 2018 at 21:16
  • $\begingroup$ No sorry I may have confused you with my notation, my $\rho$ is probably different to your $\rho$ in your question - my $\rho$ is the charge density of the sphere (which I have assumed to be constant). Perhaps it is something different, though I'm not quite sure to what it is referring, sorry. $\endgroup$
    – Garf
    Commented Sep 11, 2018 at 21:37
  • $\begingroup$ my $\rho$ or $\rho_s$ is the surface charge density $\endgroup$
    – Undergrad2019
    Commented Sep 11, 2018 at 21:40

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