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\usepackage{amsmath} |
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\begin{filecontents}[overwrite]{galois-theory-notes.bib} |
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@misc{ianstewart, |
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author = {Ian Stewart}, |
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title = {{Galois Theory, Third Edition}}, |
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year = {2004} |
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} |
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\end{filecontents} |
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\title{Galois Theory notes} |
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\author{arnaucube} |
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\date{2023-2024} |
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\begin{document} |
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\maketitle |
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\begin{abstract} |
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Notes taken while studying Galois Theory, mostyly from Ian Stewart's book "Galois Theory" \cite{ianstewart}. |
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Usually while reading books and papers I take handwritten notes in a notebook, this document contains some of them re-written to $LaTeX$. |
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The notes are not complete, don't include all the steps neither all the proofs. |
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\end{abstract} |
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\tableofcontents |
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\section{Recap on the degree of field extensions} |
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\begin{defn}{4.10} |
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A \emph{simple extension} is $L:K$ such that $L=K(\alpha)$ for some $\alpha \in L$. |
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\end{defn} |
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\begin{eg}{4.11} |
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Beware, $L=\mathbb{Q}(i, -i, \sqrt{5}, -\sqrt{5}) = \mathbb{Q}(i, \sqrt{5}) = \mathbb{Q}(i+\sqrt{5})$. |
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\end{eg} |
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\begin{defn}{5.5} |
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Let $L:K$, suppose $\alpha \in L$ is algebraic over $K$. Then, the \emph{minimal polynomial} of $\alpha$ over $K$ is the unique monic polynomial $m$ over $K$, $m(t) \in K[t]$, of smallest degree such that $m(\alpha)=0$. |
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\\ |
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eg.: $i \in \mathbb{C}$ is algebraic over $\mathbb{R}$. The minimal polynomial of $i$ over $\mathbb{R}$ is $m(t)=t^2 +1$, so that $m(i)=0$. |
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\end{defn} |
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\begin{lemma}{5.9} |
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Every polynomial $a \in K[t]$ is congruent modulo $m$ to a unique polynomial of degree $< \delta m$. |
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\end{lemma} |
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\begin{proof} |
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Divide $a / m$ with remainder, $a= qm +r$, with $q,r \in K[t]$ and $\delta r < \delta m$. |
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Then, $a-r=qm$, so $a \equiv r \pmod{m}$. |
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It remains to prove uniqueness. |
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Suppose $\exists~ r \equiv s \pmod{m}$, with $\delta r, \delta s < \delta m$. |
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Then, $r-s$ is divisible by $m$, but has smaller degree than $m$. |
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Therefore, $r-s=0$, so $r=s$, proving uniqueness. |
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\end{proof} |
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\begin{lemma}{5.14} |
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Let $K(\alpha):K$ be a simple algebraic extension, let $m$ be the minimal polynomial of $\alpha$ over $K$, let $\delta m =n$. |
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Then $\{1, \alpha, \alpha^2, \ldots, \alpha^{n-1}\}$ is a basis for $K(\alpha)$ over $K$. |
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In particular, $[K(\alpha):K]=n$. |
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\end{lemma} |
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\begin{defn}{6.2} |
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The degree $[L:K]$ of a field extension $L:K$ is the dimension of L considered as a vector space over $K$. |
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Equivalently, the dimension of $L$ as a vector space over $K$ is the number of terms in the expression for a general element of $L$ using coefficients from $K$. |
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\end{defn} |
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\begin{eg}{6.3} |
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\begin{enumerate} |
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\item $\mathbb{C}$ elements are 2-dimensional over $\mathbb{R}$ ($p+qi \in \mathbb{C}$, with $p,q \in \mathbb{R}$), because a basis is $\{1, i\}$, hence $[\mathbb{C}:\mathbb{R}]=2$. |
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\item $[ \mathbb{Q}(i, \sqrt{5}) : \mathbb{Q}]=4$, since the elements $\{1, \sqrt{5}, i, i\sqrt{5}\}$ form a basis for $\mathbb{Q}(i, \sqrt{5})$ over $\mathbb{Q}$. |
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\end{enumerate} |
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\end{eg} |
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\begin{thm}{6.4}\emph{(Short Tower Law)} |
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If $K, L, M \subseteq \mathbb{C}$, and $K \subseteq L \subseteq M$, then $[M:K]=[M:L]\cdot [L:K]$. |
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\end{thm} |
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\begin{proof} |
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Let $(x_i)_{i \in I}$ be a basis for $L$ over $K$, |
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let $(y_j)_{j \in J}$ be a basis for $M$ over $L$.\\ |
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$\forall i \in I, j \in J$, we have $x_i \in L, u_j \in M$. |
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\\ |
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Want to show that $(x_i y_j)_{i\in I, j\in J}$ is a basis for $M$ over $K$. |
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\begin{enumerate}[i.] |
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\item prove linear independence:\\ |
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Suppose that |
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$$\sum_{ij} k_{ij} x_i y_j = 0 ~(k_{ij} \in K)$$ |
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rearrange |
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$$\sum_j (\underbrace{\sum_i k_{ij} x_i}_{\in L}) y_j = 0 ~(k_{ij} \in K)$$ |
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Since $\sum_i k_{ij} x_i \in L$, and the $y_j \in M$ are linearly independent over $L$, then $\sum_i k_{ij} x_i = 0$. |
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\\ |
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Repeating the argument inside $L$ $\longrightarrow$ $k_{ij}=0 ~~\forall i\in I, j\in J$. |
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\\ |
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So the elements $x_i y_j$ are linearly independent over $K$. |
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\item prove that $x_i y_j$ span $M$ over $K$:\\ |
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Any $x \in M$ can be written $x=\sum_j \lambda_j y_j$ for $\lambda_j \in L$, because $y_j$ spans $M$ over $L$. |
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Similarly, $\forall j\in J,~ \lambda_j = \sum_i \lambda_{ij} x_i y_j$ for $\lambda_{ij} \in K$.\\ |
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Putting the pieces together, $x=\sum_{ij} \lambda_{ij} x_i y_j$ as required. |
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\end{enumerate} |
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\end{proof} |
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\begin{cor}{6.6}\emph{(Tower Law)}\\ |
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If $K_0 \subseteq K_1 \subseteq \ldots \subseteq K_n$ are subfields of $\mathbb{C}$, then |
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$$[K_n:K_0] = [K_n:K_{n-1}] \cdot [K_{n-1}:K_{n-2}] \cdot \ldots \cdot [K_1: K_0]$$ |
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\end{cor} |
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\bibliographystyle{unsrt} |
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\bibliography{galois-theory-notes.bib} |
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\end{document} |