Respuesta :
Answer:
1.[tex]E(r) = \frac{\alpha}{4\pi \epsilon_0}(2 - \frac{r}{R})[/tex]
2.[tex]E(r) = \frac{1}{4\pi \epsilon_0}\frac{\alpha R}{r}[/tex]
3.The results from part 1 and 2 agree when r = R.
Explanation:
The volume charge density is given as
[tex]\rho (r) = \alpha (1-\frac{r}{R})[/tex]
We will investigate this question in two parts. First r < R, then r > R. We will show that at r = R, the solutions to both parts are equal to each other.
1. Since the cylinder is very long, Gauss’ Law can be applied.
[tex]\int {\vec{E}} \, d\vec{a} = \frac{Q_{enc}}{\epsilon_0}[/tex]
The enclosed charge can be found by integrating the volume charge density over the inner cylinder enclosed by the imaginary Gaussian surface with radius ‘r’. The integration of E-field in the left-hand side of the Gauss’ Law is not needed, since E is constant at the chosen imaginary Gaussian surface, and the area integral is
[tex]\int\, da = 2\pi r h[/tex]
where ‘h’ is the length of the imaginary Gaussian surface.
[tex]Q_{enc} = \int\limits^r_0 {\rho(r)h} \, dr = \alpha h \int\limits^r_0 {(1-r/R)} \, dr = \alpha h (r - \frac{r^2}{2R})\left \{ {{r=r} \atop {r=0}} \right. = \alpha h (\frac{2Rr - r^2}{2R})\\E2\pi rh = \alpha h \frac{2Rr - r^2}{2R\epsilon_0}\\E(r) = \alpha \frac{2R - r}{4\pi \epsilon_0 R}\\E(r) = \frac{\alpha}{4\pi \epsilon_0}(2 - \frac{r}{R})[/tex]
2. For r> R, the total charge of the enclosed cylinder is equal to the total charge of the cylinder. So,
[tex]Q_{enc} = \int\limits^R_0 {\rho(r)h} \, dr = \alpha \int\limits^R_0 {(1-r/R)h} \, dr = \alpha h(r - \frac{r^2}{2R})\left \{ {{r=R} \atop {r=0}} \right. = \alpha h(R - \frac{R^2}{2R}) = \alpha h\frac{R}{2} \\E2\pi rh = \frac{\alpha Rh}{2\epsilon_0}\\E(r) = \frac{1}{4\pi \epsilon_0}\frac{\alpha R}{r}[/tex]
3. At the boundary where r = R:
[tex]E(r=R) = \frac{\alpha}{4\pi \epsilon_0}(2 - \frac{r}{R}) = \frac{\alpha}{4\pi \epsilon_0}\\E(r=R) = \frac{1}{4\pi \epsilon_0}\frac{\alpha R}{r} = \frac{\alpha}{4\pi \epsilon_0}[/tex]
As can be seen from above, two E-field values are equal as predicted.
The electric flux in an area is equal to the product of the electric field and the area of the surface. The electric field as a function of r can be derived by the expression is
[tex]E(r) = \dfrac {\alpha }{4\pi \epsilon _0}(2 - \frac rR)[/tex]
What is Gauss Law?
The electric flux in an area is equal to the product of the electric field and the area of the surface.
[tex]\int\limits \vec E \ \vec da = \dfrac Q {\epsilon _0}[/tex]
Integrate the left side of gauss's law with the volume charge density,
[tex]Q = \int\limits^a_b \rho (r) \ h \ dr \\[/tex]
Since,
[tex]\rho( r )= \alpha (1 - \dfrac rR)[/tex]
So,
[tex]Q = \alpha h \int\limits^r_0 (1 - \dfrac rR) dr\\\\Q = \alpha r (\dfrac {2r- r^2}{2r})[/tex]
Thus,
[tex]E(r) = \dfrac {\alpha }{4\pi \epsilon _0}(2 - \frac rR)[/tex]
Therefore, the electric field as a function of r can be derived by the expression is
[tex]E(r) = \dfrac {\alpha }{4\pi \epsilon _0}(2 - \frac rR)[/tex]
To know more about Gauss Law:
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