Suppose $k$ is a field.
How to prove that the abelianization of $GL_2(k)$ is $GL_1(k)$ ?
Ditto for $GL_n(k)$.
Can we say the same thing, were we to replace $k$ with $\mathbb Z$ ?
Suppose $k$ is a field.
How to prove that the abelianization of $GL_2(k)$ is $GL_1(k)$ ?
Ditto for $GL_n(k)$.
Can we say the same thing, were we to replace $k$ with $\mathbb Z$ ?
For any field $k$, the abelianization of $GL_n(k)$ is $k^{\ast}$ except for $n=2$ and $k=\mathbb{F}_2$ or $\mathbb{F}_3$. I think this is in Lang's Algebra, Chapter XIII sections 8 and 9. (I say I think because I am relying on google books here, and some key pages are missing.)
EDIT: I just looked back at this old answer, and the abelianization of $GL_2(\mathbb{F}_3)$ is $\mathbb{F}_3^{\times}$ as well, so $GL_2(\mathbb{F}_2)$ is the only counterexample. I think that what I was thinking when I wrote this is that the abelianization of $SL_2(\mathbb{F}_3)$ in nontrivial.
As HenrikRueping points out, the determinant map $\det:\textrm{GL}_n(k) \longrightarrow k^\ast$ factors through the abelianization $\textrm{GL}_n(k)_{ab}$ of $\textrm{GL}_n(k)$. The induced morphism $\textrm{GL}_n(k)_{ab} \longrightarrow k^\ast$ can be shown to be an isomorphism as follows. It's clearly surjective. Thus, we have to show injectivity. To do so, you have to show that each element of $\textrm{SL}_n(k)$ is a commutator.
For $n=2$, I thought one could generate $\textrm{SL}_2(k)$ with the two matrices
$\left( \begin{array}{cc} 1& 1 \\ 0 & 1 \end{array}\right)$
$\left( \begin{array}{cc} 0& 1 \\ -1 & 0 \end{array}\right)$
So if you just show that these are commutators you're done, right?
Jim points out that these matrices do not generate $\textrm{SL}_2(k)$ but $\textrm{SL}_2(\mathbf{Z})$.