Let $n$ be a positive integer, and define a map $\beta : GL(n, \mathbb{C}) \rightarrow GL(2n, \mathbb{R})$ by
$$ \beta \begin{pmatrix} a^1_1 + i b^1_1 & \cdots & a^n_1 + i b^n_1\\ \vdots & & \vdots \\ a^1_n + i b^1_n & \cdots & a^n_n + i b^n_n\\ \end{pmatrix} = \begin{pmatrix} \begin{matrix} a^1_1 & -b^1_1 \\ b^1_1 & a^1_1 \\ \end{matrix} & \cdots & \begin{matrix} a^n_1 & -b^n_1 \\ b^n_1 & a^n_1 \\ \end{matrix}\\ \vdots & & \vdots \\ \begin{matrix} a^1_n & -b^1_n \\ b^1_n & a^1_n \\ \end{matrix} & \cdots & \begin{matrix} a^n_n & -b^n_n \\ b^n_n & a^n_n \\ \end{matrix}\\ \end{pmatrix} $$
My book, Lee's Smooth Manifolds(2nd Ed), on pp. 158, stats that
It is straightforward to verify that $\beta$ is an injective Lie group homomorphism whose image is a properly embedded Lie subgroup of $GL(2n, \mathbb{R})$.
In the previous page, there are two propositions as followings
Let $F:G\rightarrow H $ be a Lie group homomorphism. The kernel of $F$ is a properly embedded Lie subgroup of $G$, whose codimension is equal to the rank of $F$.
If $F: G \rightarrow H$ is an injective Lie group homomorphism, the image of $F$ has a unique smooth manifold structure such that $F(G)$ is a Lie subgroup of $H$ and $F:G \rightarrow F(G)$ is a Lie group isomorphism. (In the proof, $F(G)$ turns out just an immersed submanifold.)
I expected that the image of $\beta$ is just an immersed submanifold by the second proposition. However the author says the result of the first proposition. So I tried to prove it directly. Since the image is clearly a closed subset of $GL(2n,\mathbb{R})$, we need only to show that $\beta$ is a topological embedding. I got stuck on this point. I want to have help. Thank you.
