When using the pumping lemma, while you are allowed to choose the string to pump (let's call it w), you are *not* allowed to choose how to split w into three parts xyz. Instead, what you need to do is show that for *any* way that w could be split into xyz, there is some choice of i such that xy^{i}z such that xy^{i}z ∉ L_{neq}. So while you are correct that if y = 0 then the string can be taken out of L_{neq}, you cannot guarantee that y = 0. Instead, you'd need to show that for any choice of y such that |xy| ≤ m and |y| > 0, you can take the string out of the language.

As a hint, try the string 0^{m}1^{m}. Now, for any choice of y, since |xy| ≤ m, you know that y must have the form 0^{j} for some natural number j > 0. Your argument then can be used to show that xy^{i}z is no longer in L_{neq}.

For another resource on the pumping lemma and how these proofs work, feel free to check out **these lecture slides** I used earlier this quarter in a theory of computation course. They walk through a few pumping lemma examples, and (importantly) show off the *adversarial model* for thinking about these proofs.

Hope this helps!