the difference of two odd squares is always a multiple of 8

Since it was stipulated that $m$ and $n$ are both odd, we can rewrite them as $m=2a+1$ and $n=2b+1$. The square of $m$ is then $m^2=(2a+1)(2a+1)=4a^2+2a+2a+1$, which simplifies to $4a^2+4a+1$. Likewise, $n^2=4b^2+4b+1$. Their difference is then $(4a^2+4a+1)-(4b^2+4b+1)=(4a^2+4a)-(4b^2+4b)$. This can’t be reduced to fewer terms. However, either side can be rewritten so as to not explicitly use squaring: $4a^2+4a=4a(a+1)$. This reveals that either the left-hand or right-hand side of our subtraction is a number that is four times a pronic number, that is, a number of the form $a(a+1)$. All pronic numbers are even, but at this point we can’t distinguish between singly even numbers and doubly even numbers. But, as it turns out, each pronic number is twice a triangular number, which is an integer. So $4a(a+1)$ is eight times some triangular number $T_c$, and $4b^2+4b=8T_d$. We rewrite our subtraction yet again: $m^2-n^2=8T_c-8T_d$. By redistributing, we get $m^2-n^2=8(T_c-T_d)$, proving the theorem. ∎