Let $D \subset \mathbb{C}$ be an open, connected set and let $\{ u_n \}$ be a sequence of harmonic functions with $u_n: D \longrightarrow (0, \infty)$. Show that if $u_n(z_0) \rightarrow 0$ for some $z_0 \in D$, then $u_n \rightarrow 0$ uniformly on compact subsets of $D$.
If you could offer a hint or a helpful question to get me started I'd appreciate it.
Progress: I now see why showing it for the unit disk suffices (any compact subset in $D$ can be covered by finitely many disks each which is contained in $D$).
I think you should use identity theorem for harmonic functions...
Let $D_1$ be a disc with a center at $z_0$, and $D_1\subseteq D$. For every $n$ $u_n$ has harmonic conjugate $v_n$. So we can define new sequence of analytic function $\lbrace f_n\rbrace$ on $D_1$.
$f_n = u_n + iv_n$.
Let $f = \lim_{n\to\infty}f_n$.
From Morera`s theorem $f$ is analytic on $D_1$, if, of course $D_1$ is small enough (maybe this is not so obvious).
Now define $g = \exp(f)$ and apply minimum principle to $g$. $|g(z_0)| = 1$ on $D_1$, so $f$ is constance on $D_1$, so $Ref = 0$ on $D_1$. Now you can apply identity theorem for harmonic function.