I am reading Deligne: Hodge III, and am puzzled by a certain statement in section 10. If anyone could give a reference or a hint for how to prove this, I would be grateful. Maybe it is obvious and I just don't see why.
We consider an extension $G$ of an abelian variety by a torus. Then Deligne claims that the kernel of the exponential map $Lie(G) \to G$ can be identified with $H_1(G, \mathbb{Z} )$. Why is this true?
The exponential map realizes Lie(G) as the universal covering space of G, and the kernel is group of covering transformations. Thus the kernel is $\pi_1(G)$, which, being commutative in this case, equals $H_1(G,Z)$. (I assume we are over the complex numbers.)
This morally sounds like it should be related to the exponential sequence in sheaf cohomology, but I don't immediately see how... Although, absent the torus (which I take as meaning $(\mathbb{C}^\times)^n$), the exponential sequence there reads $$ H^1(A, \mathbb{Z}) \to H^1(A, \mathcal{O})\ \xrightarrow{\exp}\ H^1(A, \mathcal{O}^\times) $$ and (at least over $\mathbb{C}$) we have that $H^1(A,\mathcal{O}) \cong H^1(A, \mathbb{R}) \cong T_0^*A = \mathfrak{a}^\vee$. I know this isn't exactly what you're looking for, but it looks too similar to be completely off base.
