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Math 401, Fall 2025: Thesis notes, S4, Complex manifolds
Complex Manifolds
This section extends from our previous discussion of smooth manifolds in Math 401, R2.
For this week [10/21/2025], our goal is to understand the Riemann-Roch theorem and its applications.
References:
Holomorphic vector bundles
Definition of real vector bundle
Let M be a topological space, A real vector bundle over M is a topological space E together with a surjective continuous map \pi:E\to M such that:
- For each
p\in M, the fiberE_p=\pi^{-1}(p)overpis endowed with the structure of a $k$-dimensional real vector space. - For each
p\in M, there exists an open neighborhoodUofpand a homeomorphism\Phi: \pi^{-1}(U)\to U\times \mathbb{R}^kcalled a local trivialization such that:- $\pi^{-1}(U)=\pi$(where
\pi_U:U\times \mathbb{R}^k\to \pi^{-1}(U)is the projection map) - For each
q\in U, the map\Phi_q: E_q\to \mathbb{R}^kis isomorphism fromE_qto\{q\}\times \mathbb{R}^k\cong \mathbb{R}^k.
- $\pi^{-1}(U)=\pi$(where
Definition of complex vector bundle
Let M be a topological space, A complex vector bundle over M is a real vector bundle E together with a complex structure on each fiber E_p that is compatible with the complex vector space structure.
- For each
p\in M, the fiberE_p=\pi^{-1}(p)overpis endowed with the structure of a $k$-dimensional complex vector space. - For each
p\in M, there exists an open neighborhoodUofpand a homeomorphism\Phi: \pi^{-1}(U)\to U\times \mathbb{C}^kcalled a local trivialization such that:- $\pi^{-1}(U)=\pi$(where
\pi_U:U\times \mathbb{C}^k\to \pi^{-1}(U)is the projection map) - For each
q\in U, the map\Phi_q: E_q\to \mathbb{C}^kis isomorphism fromE_qto\{q\}\times \mathbb{C}^k\cong \mathbb{C}^k.
- $\pi^{-1}(U)=\pi$(where
Definition of smooth complex vector bundle
If above M and E are smooth manifolds, \pi is a smooth map, and the local trivializations can be chosen to be diffeomorphisms (smooth bijections with smooth inverses), then the vector bundle is called a smooth complex vector bundle.
Definition of holomorphic vector bundle
If above M and E are complex manifolds, \pi is a holomorphic map, and the local trivializations can be chosen to be biholomorphic maps (holomorphic bijections with holomorphic inverses), then the vector bundle is called a holomorphic vector bundle.
Holomorphic line bundles
A holomorphic line bundle is a holomorphic vector bundle with rank 1.
Intuitively, a holomorphic line bundle is a complex vector bundle with a complex structure on each fiber.
Simplicial, Sheafs, Cohomology and homology
What is homology and cohomology?
This section is based on extension for conversation with Professor Feres on [11/05/2025].
Definition of meromorphic function
Let Y be an open subset of X. A function f is called meromorphic function on Y, if there exists a non-empty open subset Y'\subset Y such that
f:Y'\to \mathbb{C}is a holomorphic function.A=Y\setminus Y'is a set of isolated points (called the set of poles)\lim_{x\to p}|f(x)|=+\inftyfor allp\in A
Basically, a local holomorphic function on
Y.
De Rham Theorem
This is analogous to the Stoke's Theorem on chains, \int_c d\omega=\int_{\partial c} \omega.
H_k(X)\cong H^k(X)
Where H_k(X) is the $k$-th homology of X, and H^k(X) is the $k$-th cohomology of X.
Simplicial Cohomology
Riemann surfaces admit triangulations. The triangle are 2 simplices. The edges are 1 simplices. the vertices are 0 simplices.
Our goal is to build global description of Riemann surfaces using local description on each triangulation.
Singular Cohomology
Riemann-Roch Theorem (Theorem 9.64)
Suppose M is a connected compact Riemann surface of genus g, and L\to M is a holomorphic line bundle. Then
\dim \mathcal{O}(M;L)=\deg L+1-g+\dim \mathcal{O}(M;K\otimes L^*)