๐๐ฝโโ๏ธGalois Theory Unit 3 โ Splitting Fields and Algebraic Closures
Splitting fields and algebraic closures are fundamental concepts in Galois theory. They provide a framework for understanding polynomial roots and field extensions, allowing us to analyze the structure of algebraic equations and their solutions. These concepts are crucial for studying Galois groups, which reveal symmetries in polynomial equations. Splitting fields help us factor polynomials completely, while algebraic closures ensure every polynomial has roots, forming the basis for advanced algebraic and geometric theories.
Study Guides for Unit 3 โ Splitting Fields and Algebraic Closures
Key Concepts and Definitions
- A field $F$ is a set with two binary operations, addition and multiplication, satisfying the field axioms (associativity, commutativity, distributivity, identity elements, and inverses)
- A field extension $K/F$ consists of a field $K$ containing a subfield $F$, where $K$ is a vector space over $F$
- The degree of the extension, denoted $[K:F]$, is the dimension of $K$ as a vector space over $F$
- An element $\alpha \in K$ is algebraic over $F$ if it is a root of some non-zero polynomial $f(x) \in F[x]$
- The minimal polynomial of $\alpha$ over $F$ is the monic polynomial $m_\alpha(x) \in F[x]$ of lowest degree such that $m_\alpha(\alpha) = 0$
- A field extension $K/F$ is algebraic if every element of $K$ is algebraic over $F$
- A splitting field of a polynomial $f(x) \in F[x]$ is a field extension $K/F$ such that $f(x)$ factors completely into linear factors in $K[x]$ and $K$ is generated by the roots of $f(x)$
Field Extensions Revisited
- A field extension $K/F$ can be viewed as a vector space over $F$, with the elements of $K$ forming a basis
- The degree of the extension $[K:F]$ is the dimension of this vector space
- For finite extensions, $[K:F] = n$ means that every element of $K$ can be uniquely expressed as a linear combination of basis elements with coefficients in $F$
- Tower Law for field extensions: if $L/K$ and $K/F$ are field extensions, then $[L:F] = [L:K][K:F]$
- Primitive element theorem: if $K/F$ is a finite separable extension, then $K = F(\alpha)$ for some $\alpha \in K$ (i.e., $K$ is generated by a single element over $F$)
- Normal extensions: a field extension $K/F$ is normal if every irreducible polynomial in $F[x]$ that has a root in $K$ splits completely in $K[x]$
Introduction to Splitting Fields
- A splitting field of a polynomial $f(x) \in F[x]$ is a field extension $K/F$ such that:
- $f(x)$ factors completely into linear factors in $K[x]$
- $K$ is generated by the roots of $f(x)$
- The splitting field is the smallest field extension of $F$ in which $f(x)$ splits completely
- It is unique up to isomorphism
- Examples:
- The splitting field of $x^2 - 2$ over $\mathbb{Q}$ is $\mathbb{Q}(\sqrt{2})$
- The splitting field of $x^3 - 2$ over $\mathbb{Q}$ is $\mathbb{Q}(\sqrt[3]{2}, \omega)$, where $\omega$ is a primitive cube root of unity
Constructing Splitting Fields
- To construct the splitting field of a polynomial $f(x) \in F[x]$:
- Factor $f(x)$ into irreducible factors over $F$
- Adjoin a root of each irreducible factor to $F$ to obtain a larger field
- Repeat step 2 until $f(x)$ splits completely
- The splitting field is the smallest field containing all the roots of $f(x)$
- The degree of the splitting field over $F$ is divisible by the degree of $f(x)$
- If $f(x)$ is separable, then the degree of the splitting field is equal to the order of the Galois group of $f(x)$ over $F$
- Examples:
- Constructing the splitting field of $x^4 - 2$ over $\mathbb{Q}$:
- $x^4 - 2 = (x^2 - \sqrt{2})(x^2 + \sqrt{2})$ over $\mathbb{Q}(\sqrt{2})$
- Adjoin $i$ to obtain the splitting field $\mathbb{Q}(\sqrt{2}, i)$
- Constructing the splitting field of $x^4 - 2$ over $\mathbb{Q}$:
Properties of Splitting Fields
- The splitting field of a polynomial $f(x) \in F[x]$ is unique up to isomorphism
- The splitting field of $f(x)$ over $F$ is the smallest field extension of $F$ in which $f(x)$ splits completely
- If $K$ is the splitting field of $f(x)$ over $F$, then $K/F$ is a normal extension
- Every irreducible polynomial in $F[x]$ that has a root in $K$ splits completely in $K[x]$
- If $f(x)$ is separable, then the splitting field of $f(x)$ over $F$ is a Galois extension
- The Galois group of the splitting field is isomorphic to a subgroup of the permutation group of the roots of $f(x)$
- The splitting field of a polynomial is the smallest field containing all the roots of the polynomial
Algebraic Closures: Definition and Existence
- An algebraic closure of a field $F$ is an algebraic extension $\overline{F}$ of $F$ such that every non-constant polynomial in $\overline{F}[x]$ has a root in $\overline{F}$
- Equivalently, $\overline{F}$ is algebraically closed: every non-constant polynomial in $\overline{F}[x]$ splits completely in $\overline{F}[x]$
- Every field $F$ has an algebraic closure $\overline{F}$
- The proof relies on Zorn's Lemma, a powerful tool in set theory
- The algebraic closure of a field is unique up to isomorphism
- Examples:
- The algebraic closure of $\mathbb{R}$ is $\mathbb{C}$
- The algebraic closure of $\mathbb{Q}$ is $\overline{\mathbb{Q}}$, the field of algebraic numbers
Uniqueness of Algebraic Closures
- Any two algebraic closures of a field $F$ are isomorphic as $F$-algebras
- The isomorphism is unique if we require it to fix $F$ pointwise
- The proof of uniqueness relies on the following steps:
- Show that any $F$-homomorphism between algebraic closures is an isomorphism
- Use Zorn's Lemma to extend an $F$-homomorphism between subfields of algebraic closures to the entire algebraic closures
- As a consequence, we can speak of "the" algebraic closure of a field $F$, denoted $\overline{F}$
- The uniqueness of algebraic closures is a powerful tool in Galois theory, as it allows us to compare different algebraic extensions of a field
Applications and Examples
- Splitting fields are used to study the Galois group of a polynomial
- The Galois group of a polynomial $f(x)$ over $F$ is the group of automorphisms of the splitting field of $f(x)$ that fix $F$ pointwise
- Algebraic closures are used to study the absolute Galois group of a field
- The absolute Galois group of $F$ is the Galois group of $\overline{F}/F$
- Splitting fields and algebraic closures are essential in the study of algebraic geometry
- Algebraic varieties are defined as solution sets of polynomial equations over an algebraically closed field
- Examples:
- The splitting field of $x^n - 1$ over $\mathbb{Q}$ is $\mathbb{Q}(\zeta_n)$, where $\zeta_n$ is a primitive $n$-th root of unity
- The Galois group of this splitting field is isomorphic to $(\mathbb{Z}/n\mathbb{Z})^\times$, the multiplicative group of integers modulo $n$
- The algebraic closure of a finite field $\mathbb{F}_q$ is the infinite field $\overline{\mathbb{F}}q$, which is the union of all finite fields $\mathbb{F}{q^n}$ for $n \geq 1$
- The splitting field of $x^n - 1$ over $\mathbb{Q}$ is $\mathbb{Q}(\zeta_n)$, where $\zeta_n$ is a primitive $n$-th root of unity
Common Pitfalls and Misconceptions
- Not every field extension is a splitting field
- For example, $\mathbb{Q}(\sqrt{2})$ is not a splitting field over $\mathbb{Q}$, as $x^2 - 2$ does not split completely in this extension
- Not every algebraic extension is a Galois extension
- For example, $\mathbb{Q}(\sqrt[3]{2})$ is not a Galois extension of $\mathbb{Q}$, as it is not a normal extension
- The algebraic closure of a field is not necessarily complete with respect to a given metric
- For example, $\overline{\mathbb{Q}}$ is not complete with respect to the usual Euclidean metric
- The algebraic closure of a field is not necessarily a computable object
- While the algebraic closure of $\mathbb{Q}$ is countable, there is no explicit description of its elements
- The Galois group of a polynomial is not always isomorphic to the full permutation group of its roots
- The Galois group is isomorphic to a subgroup of the permutation group, determined by the specific polynomial and base field