161 lines
7.9 KiB
TeX
161 lines
7.9 KiB
TeX
\section{Introduction}
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\stoptocentries % Personal macro: Following sections shouldn't appear in toc
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\subsection*{Contents of the thesis}\;
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The Hodge Decomposition theorem for compact Kähler manifolds is a fundamental theorem of the Hodge
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Theory. It provides a decomposition of the de Rahm cohomology groups into suitable Dolbeault
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cohomology groups, thus yielding a connection between the topology and the complex structure of a
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compact Kähler manifold.
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\begin{thm}[Hodge Decomposition]
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For a compact Kähler manifold $X$, there is a direct sum decomposition
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\begin{align*}
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H^k_{dR}(X,\mathbb{C}) = \bigoplus_{p+q=k} H^{p,q}_{\opartial}(X,\mathbb{C}).
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\end{align*}
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\end{thm}
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The primary objective of this thesis will be the elaboration of the proof of this fundamental
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theorem. In order to achieve this, we will have to introduce the needed theory first. We are going
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to start by presenting the consequences of the existence of an almost complex structure and a
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compatible euclidean inner product on a real vector space. For this purpose, we will mainly use the
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tools of Linear Algebra.
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With this, we will be able to define the local versions of the \emph{Hodge star operator}
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$\hodgestar$ and the \emph{Lefschetz} and dual \emph{Lefschetz operators} $L$ and $\Lambda$.
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Afterwards, our focus is going to shift to complex manifolds and their different tangent bundles.
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Although it is assumed that the reader is already familiar with the definition and basic properties
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of complex manifolds, we will begin with the definition and also the elaboration of the properties
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of hermitian manifolds, which are the complex counterparts of Riemannian manifolds.
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After we have used our local findings for the operators mentioned above to define similarly named
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global operators for hermitian manifolds, we will also introduce an \emph{$L^2$-metric} that will be
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used to generalize the idea of adjoint operators to \emph{formal adjoint opertors}. We will be
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particularly interested in the formal adjoint operators of the exterior derivative $d$ and the
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Dolbeault operators $\partial$ and $\opartial$, which will be noted as $d^*,\partial^*$ and
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$\opartial^*$.
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Those formal adjoint operators will particularly interest us because they appear in the \emph{Kähler
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identities}. These identities relate the Dolbeault operators and their formal adjoints to each other
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using the dual Lefschetz operator.
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\begin{thm}
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On a compact Kähler manifold, we have the identities
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\begin{align*}
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[\Lambda,\opartial] = -i\partial^*, \quad [\Lambda,\partial] = i\opartial^*,
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\end{align*}
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with the Lie bracket being defined as the commutator.
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\end{thm}
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Next, we are going to introduce the theory of \emph{harmonic differential forms}. In order to do so,
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we will define the \emph{Laplacians} $\Delta_d, \Delta_\partial$ and $\Delta_\opartial$ and work out
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their properties. We will then use the \emph{Kähler identities} to prove the next important theorem.
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\begin{thm}
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For the Laplacians $\Delta_d, \Delta_\partial$ and $\Delta_\opartial$ on a compact Kähler manifold,
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we have the following relation
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\begin{align*}
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\frac{1}{2}\Delta_d = \Delta_\partial = \Delta_\opartial.
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\end{align*}
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\end{thm}
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Since harmonic and $\Delta_\opartial$-harmonic forms will be defined as forms annihilated by
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$\Delta_d$ and $\Delta_\opartial$, respectively, this theorem shows that those two notions are
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equivalent for Kähler manifolds. Furthermore, we will use this theorem to establish the following
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corollary, which will be crucial for proving the \emph{Hodge Decomposition} theorem.
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\begin{cor}
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For the compact Kähler manifold $X$, the complex harmonic differential $k$-forms $\mathcal{H}^k(X)$
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decompose as
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\begin{align*}
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\mathcal{H}^k(X) = \bigoplus_{p+q=k}\mathcal{H}^{p,q}(X),
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\end{align*}
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with $\mathcal{H}^{p,q}(X)$ being the harmonic differential forms of type $(p,q)$.
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\end{cor}
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The final statements needed for our proof of the \emph{Hodge Decomposition} theorem will be the
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\emph{Hodge Isomorphism theorems}, which enable us to apply the findings of the harmonic forms
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theory to the de Rahm and Dolbeault cohomologies by providing two isomorphisms.
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\begin{thm}[Hodge Isomorphism theorem \MakeUppercase{\romannumeral 1}]
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The natural mapping
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\begin{align*}
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\mathcal{H}^k(X) \rightarrow H^k_{dR}(X,\mathbb{C}), \;\enspace
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\alpha \mapsto [\alpha]
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\end{align*}
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is an isomorphism. In particular, any class of closed forms in $H^k_{dR}(X,\mathbb{C})$ has a
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unique harmonic
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representative.
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\end{thm}
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\begin{thm}[Hodge Isomorphism theorem \MakeUppercase{\romannumeral 2}]
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The natural mapping
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\begin{align*}
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\mathcal{H}^{p,q}(X) \rightarrow H^{p,q}_\opartial(X,\mathbb{C}),\; \enspace \alpha \mapsto
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[\alpha]
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\end{align*}
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is an isomorphism. In particular, any class of $\opartial$-closed forms in
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$H^{p,q}_\opartial(X,\mathbb{C})$
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has a unique harmonic representative.
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\end{thm}
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After these two isomorphism theorems are proven, we already have the \emph{Hodge Decomposition}
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given as an isomorphism and in order to get the above \emph{Hodge Decomposition} theorem, we only
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need to prove the independence of the Kähler metric.
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To conclude this thesis, we will then provide an application of the \emph{Hodge Decomposition}. We
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are going to show that the \emph{Hopf surfaces}, which are compact 2-dimensional complex manifolds,
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can not be equipped with a Kähler metric.
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\subsection*{Remarks on the implementation}\;
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For the \emph{Hodge Decomposition}, several different proofs are already known. Therefore, the idea
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of this thesis is the collection and the coherent presentation of one of these possible proofs from
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the perspective of an undergraduate student who is already familiar with some of the basic concepts
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of complex and algebraic geometry.
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In this context, this thesis broadly follows the proof presented in \emph{Claire Voisin's} book
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\emph{Hodge Theory and Complex Algebraic Geometry I}. However, other popular sources have also
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influenced this thesis. Therefore, we will reference similar or equal statements in this literature
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whenever possible. This is done to allow for the possibility of verification and to encourage the
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reader to engage more deeply with the content.
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Also, since multiple different notation conventions exist in complex geometry, we will try to stick
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to the notation suggested by \emph{Voisin} in her book. However, we will also provide the reader
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with explanations for the used notation throughout the thesis so that even the unfamiliar reader
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will be able to follow.
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\subsection*{Conventions}\;
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Throughout the thesis, we are always going to limit our discussion to differentiable manifolds
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without border. In order to have a Riemannian metric on every differentiable manifold, we are also
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only going to allow paracompact manifolds.
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Additionally, we are going to adhere to the following meaning of the used symbols.
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\begin{table}[ht]
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\centering
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\begin{tabular}{cp{0.6\textwidth}}
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$\mathbb{N}$ & Natural numbers, including 0\\
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$\subset$ & Not necessarily proper subset \\
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$\subsetneq$ & Proper subset\\
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$\into$ & Injection or monomorphism\\
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$\onto$ & Surjection or epimorphism\\
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\end{tabular}
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\end{table}
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Also, the uppercase letters $J$ and $K$ will usually denote multi-indices except for one instance,
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when $J$ denotes an almost complex structure. Additionally, if there are uppercase letters in the
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index, they also denote multi-indices. For a basis vector $v_j$, we will write $v^j$ for the dual
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basis vector.
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\subsection*{Acknowledgments}\;
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I want to thank Andreas Demleitner for his advice and for his constant willingness and patience in
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answering my questions. I want to thank Alina Vogler and especially Jonathan Stahlmann for their
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advice regarding the rules of the English language. I am also very thankful for the opportunity to
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write this thesis under the supervision of Stefan Kebekus, whom I want to thank for his help and
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guidance.
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\vspace*{1.3cm}
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\begin{flushright}
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\emph{Daniel Rath}\\
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\emph{Freiburg im Breisgau}\\
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\emph{August 30, 2023}
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\end{flushright}
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\starttocentries % Personal macro: Add following sections to toc
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