I don't think it is more relevant to part (b). When I solve for $x^2$ one of my solutions is of the form
$$ x^2 = k \times (1+\sqrt{2})^2$$.

The important thing to remember is that the Bishop knows how old he/she is! So if the Bishop was 42 they would be looking for the sum of ages which sums to 84.

Start by writing down 2450 as a product of primes. You can they write down all the possible sets of ages for the three bellringers (just to be nice, I'll tell you that none of them are ages 1). You then write down the sum of their ages. The fact that the bishop cannot say what the answer is immediately indicates which are the possible sets of ages.

I will put some more explanation in the hints and partials solution document to this question!

There is now a full solution to this problem in the "Hints" document.

You are told in the "stem" of the question that $c$ is real!

You should have found a quadratic equation in $x$ [by multiplying throughout by $(x-a)(x-b)$]. It gets a bit messy but you can cancel some bits. You then find the discriminant of this and set it equal to 0. Again this gets a bit messy but you should be able to use this to show the required result $c^2=-\dfrac{4ab}{(a-b)^2}$. Note that since $c$ is real then we must have exactly one of $a$ and $b$ negative ($a,b$ are non-zero - given in the stem).

For the next "show that" it is probably easiest to start from the second condition and "work backwards". In an exam I would then either re-write it the correct way around or put something like "each of these steps can be reversed" or something similar!

The final part uses $c^2=1-\left( \dfrac{a+b}{a-b} \right)^2$ to show that $0 \lt c^2 \le 1$. You will need to use the fact that $a$ and $b$ are distinct and non-zero.