Answer:
r = 5.848cm, h = 11.696cm
Step-by-step explanation:
Surface area: [tex]SA=2\pi rh+2\pi r^2[/tex]
Volume: [tex]V=\pi r^2h[/tex]
Therefore, the height of a cylinder given its volume would be [tex]h=\frac{V}{\pi r^2}[/tex], thus:
[tex]SA=2\pi r(\frac{V}{\pi r^2})+2\pi r^2\\\\SA=\frac{2V}{r}+2\pi r^2\\\\SA=\frac{2(400\pi)}{r}+2\pi r^2\\\\SA=\frac{800\pi}{r}+2\pi r^2[/tex]
We now find the derivative of the surface area of the cylinder with respect to its radius and set it equal to 0, solving for the radius:
[tex]\frac{d(SA)}{dr}=-\frac{800\pi}{r^2}+4\pi r[/tex]
[tex]0=-\frac{800}{r^2}+4\pi r[/tex]
[tex]0=800\pi+4\pi r^3[/tex]
[tex]-800\pi=4\pi r^3[/tex]
[tex]-200=r^3[/tex]
[tex]r\approx5.848[/tex]
If [tex]0If [tex]r>5.848[/tex], then the surface area of the cylinder increases
Therefore, the surface area is minimized when the radius is [tex]r=5.848cm[/tex], making the minimum height [tex]h=\frac{V}{\pi r^2}=\frac{400\pi}{\pi(5.848)^2}\approx11.696cm[/tex].
In conclusion, the 2nd option is correct.
