Master thesis on Rational Homotopy Theory
https://github.com/Jaxan/Rational-Homotopy-Theory
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98 lines
5.7 KiB
98 lines
5.7 KiB
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\chapter{Rational homotopy theory}
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\label{sec:basics}
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In this section we will state the aim of rational homotopy theory. Moreover we will recall classical theorems from algebraic topology and deduce rational versions of them.
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In the following definition \emph{space} is to be understood as a topological space or a simplicial set.
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\Definition{rational-space}{
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A $0$-connected space $X$ with abelian fundamental group is a \emph{rational space} if
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$$ \pi_i(X) \text{ is a $\Q$-vector space } \quad \forall i > 0. $$
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The full subcategory of rational spaces is denoted by $\Top_\Q$ (or $\sSet_\Q$ when working with simplicial sets).
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}
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\Definition{rational-homotopy-groups}{
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We define the \emph{rational homotopy groups} of a $0$-connected space $X$ with abelian fundamental group as:
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$$ \pi_i(X) \tensor \Q \quad \forall i > 0.$$
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}
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In order to define the tensor product $\pi_1(X) \tensor \Q$ we need that the fundamental group is abelian, the higher homotopy groups are always abelian. There is a more general approach using \Def{nilpotent groups}, which admit $\Q$-completions \cite{bousfield}. Since this is rather technical we will often restrict ourselves to spaces as above or even simply connected spaces.
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Note that for a rational space $X$, the ordinary homotopy groups are isomorphic to the rational homotopy groups, i.e. $\pi_i(X) \tensor \Q \iso \pi_i(X)$.
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\Definition{rational-homotopy-equivalence}{
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A map $f: X \to Y$ is a \emph{rational homotopy equivalence} if $\pi_i(f) \tensor \Q$ is a linear isomorphism for all $i > 0$.
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}
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\Definition{rationalization}{
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A map $f: X \to X_0$ is a \emph{rationalization} if $X_0$ is rational and $f$ is a rational homotopy equivalence.
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}
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Note that a weak equivalence is always a rational equivalence. Furthermore if $f: X \to Y$ is a map between rational spaces, then $f$ is a rational homotopy equivalence if and only if $f$ is a weak equivalence.
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The theory of rational homotopy is the study of spaces with rational equivalences. Quillen defines a model structure on simply connected simplicial sets with rational equivalences as weak equivalences \cite{quillen}. This means that there is a homotopy category $\Ho^\Q(\sSet_1)$. However we will later prove that every simply connected space has a rationalization, so that $\Ho_\Q(\sSet_1) = \Ho(\sSet_{1,\Q})$ are equivalent categories. This means that we do not need the model structure defined by Quillen, but we can just restrict ourselves to rational spaces with ordinary weak equivalences.
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\section{Classical results from algebraic topology}
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We will now recall known results from algebraic topology, without proof. One can find many of these results in basic text books, such as \cite{may, dold}.
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\Theorem{relative-hurewicz}{
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(Relative Hurewicz Theorem) For any inclusion of spaces $Y \subset X$ and all $i > 0$, there is a natural map
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$$ h_i : \pi_i(X, Y) \to H_i(X, Y). $$
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If furthermore $(X, Y)$ is $n$-connected ($n > 0$), then the map $h_i$ is an isomorphism for all $i \leq n + 1$.
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}
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\Theorem{serre-les}{
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(Long Exact Sequence of Homotopy Groups) Let $f: X \to Y$ be a Serre fibration, then there is a long exact sequence:
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$$ \cdots \tot{\del} \pi_i(F) \tot{i_\ast} \pi_i(X) \tot{f_\ast} \pi_i(Y) \tot{\del} \cdots \to \pi_0(Y) \to \ast, $$
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where $F$ is the fiber of $f$.
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}
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Using an inductive argument and the previous two theorems, one can show the following theorem (as for example shown in \cite{griffiths}).
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\Theorem{whitehead-homology}{
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(Whitehead Theorem) For any map $f: X \to Y$ between $1$-connected spaces, $ \pi_i(f) $ is an isomorphism $\forall 0 < i < r$ if and only if $H_i(f)$ is an isomorphism $\forall 0 < i < r$.
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In particular we see that $f$ is a weak equivalence if and only if it induces an isomorphism on homology.
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}
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The following two theorems can be found in textbooks about homological algebra such as \cite{weibel, rotman}. Note that when the degrees are left out, $H(X; A)$ denotes the graded homology module with coefficients in $A$.
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\Theorem{universal-coefficient}{
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(Universal Coefficient Theorem)
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For any space $X$ and abelian group $A$, there are natural short exact sequences
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$$ 0 \to H_n(X) \tensor A \to H_n(X; A) \to \Tor(H_{n-1}(X), A) \to 0, $$
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$$ 0 \to \Ext(H_{n-1}(X), A) \to H^n(X; A) \to \Hom(H_n(X), A) \to 0. $$
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}
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\Theorem{kunneth}{
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(Künneth Theorem)
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For spaces $X$ and $Y$, there is a short exact sequence
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\[ \footnotesize \xymatrix @C=0.3cm{
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0 \ar[r] & H(X; A) \tensor H(Y; A) \ar[r] & H(X \times Y; A) \ar[r] & \Tor_{\ast-1}(H(X; A), H(Y; A)) \ar[r] & 0
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},\]
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where $H(X; A)$ and $H(X; A)$ are considered as graded modules and their tensor product and torsion groups are graded.
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}
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\section{Consequences for rational homotopy theory}
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The latter two theorems have a direct consequence for rational homotopy theory. By taking $A = \Q$ we see that the torsion groups vanish. We have the immediate corollary.
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\Corollary{rational-corollaries}{
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We have the following natural isomorphisms in rational homology, and we can relate rational cohomology naturally to rational homology
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\begin{align*}
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H_\ast(X) \tensor \Q &\tot{\iso} H_\ast(X; \Q), \\
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H_\ast(X; \Q) \tensor H_\ast(Y; \Q) &\tot{\iso} H_\ast(X \times Y; \Q), \\
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H^\ast(X; \Q) &\tot{\iso} \Hom(H_\ast(X); \Q).
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\end{align*}
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}
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The long exact sequence for a Serre fibration also has a direct consequence for rational homotopy theory.
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\Corollary{rational-les}{
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Let $f: X \to Y$ be a Serre fibration with fiber $F$, all $0$-connected with abelian fundamental group, then there is a natural long exact sequence of rational homotopy groups:
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$$ \cdots \tot{\del} \pi_i(F) \tensor \Q \tot{i_\ast} \pi_i(X) \tensor \Q \tot{f_\ast} \pi_i(Y) \tensor \Q \tot{\del} \cdots. $$
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}
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In the next sections we will prove the rational Hurewicz and rational Whitehead theorems. These theorems are due to Serre \cite{serre}.
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