Galois Theory II

Galois Theory II: The Proof

Introduction

The proof of the Fundamental Theorem of Galois Theory relies on a series of lemmas and propositions that connect the size of the automorphism group to the degree of the extension. This chapter provides a detailed outline of the proof.

Proof Outline

Step 1: Establish Equivalence for Galois Extensions

First, one proves the equivalence of the defining properties of a finite Galois extension:

It is normal and separable
It is the splitting field of a separable polynomial
$| Aut (L / K) | = [L : K]$
The fixed field of $Aut (L / K)$ is $K$

The key lemma, due to Artin, states that for any finite group of automorphisms $H$ of a field $L$ , the extension $L / L^{H}$ is Galois with group $H$ and degree $| H |$ .

Step 2: Show the Correspondence is Bijective

With these equivalences, one shows that the maps $E \mapsto Gal (L / E)$ and $H \mapsto L^{H}$ are inverses of each other. The fact that $L^{Gal (L / E)} = E$ follows because $L / E$ is itself a Galois extension. The fact that $Gal (L / L^{H}) = H$ is a direct consequence of Artin's lemma.

Step 3: Prove the Properties

The properties of the correspondence (inclusion-reversal, degrees/indices, and normality) are then proven using the established bijection and the definitions of degree, index, and normal subgroups.

Key Lemmas

Artin's Lemma

Lemma 18.1 (Artin's Lemma): Let $L$ be a field and let $H$ be a finite group of automorphisms of $L$ . Let $K = L^{H}$ be the fixed field of $H$ . Then:

$L / K$ is a Galois extension
$Gal (L / K) = H$
$[L : K] = | H |$

Proof of Artin's Lemma

The proof involves several steps:

Show that $L / K$ is algebraic: Every element of $L$ is algebraic over $K$
Show that $L / K$ is separable: The minimal polynomial of any element has distinct roots
Show that $L / K$ is normal: Every irreducible polynomial with a root in $L$ splits in $L$
Show that $H = Gal (L / K)$ : Every element of $H$ is a $K$ -automorphism, and every $K$ -automorphism is in $H$

Dedekind's Lemma

Lemma 18.2 (Dedekind's Lemma): Let $L$ be a field and let $σ_{1}, σ_{2}, \dots, σ_{n}$ be distinct automorphisms of $L$ . Then $σ_{1}, σ_{2}, \dots, σ_{n}$ are linearly independent over $L$ .

This lemma is crucial for showing that the number of automorphisms cannot exceed the degree of the extension.

The Correspondence

Definition of the Maps

Let $L / K$ be a finite Galois extension with Galois group $G = Gal (L / K)$ . We define two maps:

Field to Group: For each intermediate field $E$ (where $K \subseteq E \subseteq L$ ), we associate the subgroup of automorphisms that fix $E$ : $H = Gal (L / E)$
Group to Field: For each subgroup $H \leq G$ , we associate its fixed field: $E = L^{H} = {x \in L ∣ σ (x) = x for all σ \in H}$

Bijectivity

Theorem 18.3: The maps $E \mapsto Gal (L / E)$ and $H \mapsto L^{H}$ are inverses of each other.

Proof:

For any intermediate field $E$ , we have $L^{Gal (L / E)} = E$ because $L / E$ is a Galois extension
For any subgroup $H \leq G$ , we have $Gal (L / L^{H}) = H$ by Artin's lemma

Properties of the Correspondence

Inclusion-Reversing

Theorem 18.4: The correspondence is inclusion-reversing:

If $E_{1} \subseteq E_{2}$ , then $Gal (L / E_{2}) \leq Gal (L / E_{1})$
Conversely, if $H_{1} \leq H_{2}$ , then $L^{H_{2}} \subseteq L^{H_{1}}$

Degrees and Indices

Theorem 18.5: For any intermediate field $E$ and corresponding subgroup $H = Gal (L / E)$ :

$[L : E] = | H |$
$[E : K] = [G : H]$

Normality

Theorem 18.6: The extension $E / K$ is a normal (and thus Galois) extension if and only if its corresponding subgroup $H = Gal (L / E)$ is a normal subgroup of $G$ . In this case, the Galois group of $E / K$ is isomorphic to the quotient group $G / H$ :

Gal (E / K) ≅ G / H

Applications of the Proof

Application 1: Understanding Field Structure

The proof shows how the structure of the Galois group reflects the structure of the field extension, providing a powerful tool for understanding field theory.

Application 2: Computing Galois Groups

The correspondence allows us to compute Galois groups by understanding the intermediate fields and their relationships.

Application 3: Solvability by Radicals

The proof provides the foundation for understanding when polynomial equations can be solved by radicals, as the structure of the Galois group determines the solvability.

Examples

Example 1: Quadratic Extensions

For the extension $Q (\sqrt{2}) / Q$ :

The Galois group is ${i d, σ}$ where $σ (\sqrt{2}) = - \sqrt{2}$
The only intermediate field is $Q$ itself
The correspondence is: $Q \leftrightarrow {i d, σ}$

Example 2: Cubic Extensions

For the extension $Q (\sqrt[3]{2}, ω) / Q$ :

The Galois group is $S_{3}$ (the symmetric group on 3 letters)
The intermediate fields correspond to the subgroups of $S_{3}$
The normal subgroups correspond to normal extensions

Example 3: Cyclotomic Extensions

For the extension $Q (ζ_{n}) / Q$ where $ζ_{n}$ is a primitive $n$ -th root of unity:

The Galois group is isomorphic to $(Z / n Z)^{\times}$
The intermediate fields correspond to the subgroups of this group
All intermediate fields are normal over $Q$

Summary

The proof of the Fundamental Theorem of Galois Theory is a beautiful synthesis of field theory and group theory. It establishes a precise correspondence between the structure of field extensions and the structure of groups, providing a powerful tool for understanding both subjects.

The key insight is that the automorphisms of a field extension form a group that encodes the structure of the extension, and this group-theoretic information can be used to understand the field-theoretic properties.

This correspondence is fundamental to modern algebra and has applications throughout mathematics, from number theory to algebraic geometry to cryptography.