In mathematics, the exponential sheaf sequence is a fundamental short exact sequence of sheaves used in complex geometry.
Let M be a complex manifold, and write O<sub>M</sub> for the sheaf of holomorphic functions on M. Let O<sub>M</sub>* be the subsheaf consisting of the non-vanishing holomorphic functions. These are both sheaves of abelian groups. The exponential function gives a sheaf homomorphism
because for a holomorphic function f, exp(f) is a non-vanishing holomorphic function, and exp(f + g) = exp(f)exp(g). Its kernel is the sheaf 2ÃÂiZ of locally constant functions on M taking the values 2ÃÂin, with n an integer. The exponential sheaf sequence is therefore
The exponential mapping here is not always a surjective map on sections; this can be seen for example when M is a punctured disk in the complex plane. The exponential map is surjective on the stalks: Given a germ g of an holomorphic function at a point P such that g(P) â 0, one can take the logarithm of g in a neighborhood of P. The long exact sequence of sheaf cohomology shows that we have an exact sequence
for any open set U of M. Here H<sup>0</sup> means simply the sections over U, and the sheaf cohomology H<sup>1</sup>(2ÃÂiZ|<sub>U</sub>) is the singular cohomology of U.
One can think of H<sup>1</sup>(2ÃÂiZ|<sub>U</sub>) as associating an integer to each loop in U. For each section of O<sub>M</sub>*, the connecting homomorphism to H<sup>1</sup>(2ÃÂiZ|<sub>U</sub>) gives the winding number for each loop. So this homomorphism is therefore a generalized winding number and measures the failure of U to be contractible. In other words, there is a potential topological obstruction to taking a global logarithm of a non-vanishing holomorphic function, something that is always locally possible.
A further consequence of the sequence is the exactness of
Here H<sup>1</sup>(O<sub>M</sub>*) can be identified with the Picard group of holomorphic line bundles on M. The connecting homomorphism sends a line bundle to its first Chern class.