In Urysohn's Metrization Theorem we try to show that a space $X$ is metrizable by constructing some function $F: X\rightarrow H$ which is an embedding. Metrizability would then follow from the fact that $X$ is homeomorphic to a subspace of the Hilbert Cube.
Beneath, they try to show that $F$ is an embedding by showing that it is one-to-one, continuous andan open function.
Isn't it sufficient to show that $F$ is one-to-one and continuous? Why do we also need to show that $F$ is an open mapping? Is this the case for any embedding or is it just the case within this Theorem?
Here is the proof up until the point of constructing $F$.
Let $X$ be a second countable regular space with countable basis $\mathcal{B}=\{B_n\}_{n=1}^{\infty}$. We can easily prove $X$ is normal. Consider the collection of all ordered pairs $(i,j)$ of integers for which $\bar{B_i}\subset B_j$. By Urysohn's Lemma, there is for each such pair $(i,j)$ a Urysohn function $f: X \rightarrow [0,1]$ such that $f(\bar{B_i})=0$, $ f(X\setminus B_j)=1$.
Let $\mathcal{F}$ denote such a collection of Urysohn functions having one member for each ordered pair $(i,j)$ for which $\bar{B_i}\subset B_j$. Since $\mathcal{F}$ is countable, then it can be indexed by the set of positive integers.
Define a function $F: X \rightarrow H$ from $X$ into Hilbert space $H$ by
$$ F(x) = \left( f_1(x), \frac{f_2(x)}{2}, \frac{f_3(x)}{3}, \dots\right), x \in X$$Thus the coordinates of $F(x)$ are determined by the values of the members of $\mathcal{F}$ at $x$; each value $f_n(x)$ is divided by $n$ to insure that $F(x)$ is a member of $H$:
$$ \sum_{n=1}^{\infty}\left( \frac{f_n(x)}{n} \right)^2 \leq \sum_{n=1}^{\infty} \frac{1}{n^2}$$
so the sum of the squares of the coordinates of $F(x)$ is a convergent series of real numbers.
To show that $F$ is an embedding, it is sufficient to show that $F$ is a one-to-one, continuous and open function to the subspace $F(X)$ of $H$. Then the metrizability of $X$ will follow from the fact that $X$ is homeomorphic to a subspace of the metric space $H$.
