I am a little unsure about (b) and (d)
For (b), is it appropriate to just take the limit directly? (do I have to show that the sequence is bounded and monotone?) from $x_{n+1} = \frac{1}{2}(x_n+5/x_n)$? That is $\ell = \frac{1}{2}(\ell+5/\ell)$? Or is the question implying I should take the one in (a) instead (even though it is equivalent). I got it to $x_{n+1}^2-5 = \dfrac{1}{4x_n}(x_n^2-5)^2$
For (d), I was able to compute the tenth term on Mathematica as a fraction and and evaluated it using the numerical command.
So I thought that to show I would get the 600th decimal place, I would do $|x_{10}-\sqrt{5}| = 0.\underbrace{000...}_{600 \; \text{zeros}}1 $. On Mathematica, I got $|x_{10}-\sqrt{5}| = 0 \times 10^{600}$. Does this show I got it to the 600th place? Because I tried 601, 602, and 605 and they seem all to be $0 \times 10^{x}$. I am terrible with counting, so should I actually take the 601th place of $x_{10}$ and subtract $\sqrt{5}$'s 600th place?
EDIT
$x_{n+1}^2-5 = \dfrac{1}{4x_n}(x_n^2-5)^2 < \dfrac{(x_n^2 - 5)^2}{20}$ for all n $ \geq 2$