Galois group of a polynomial
The Galois group of a polynomial is a concept in the field of algebra, specifically within Galois theory, which studies the relationship between field extensions and group theory. The Galois group of a polynomial provides deep insights into the solvability and structure of the roots of the polynomial.
Key Concepts
1. Polynomial and Its Roots
- A polynomial f(x)f(x) with coefficients in a field KK (typically Q\mathbb{Q}, R\mathbb{R}, or C\mathbb{C}) can be written as f(x)=anxn+an−1xn−1+⋯+a0f(x) = a_n x^n + a_{n-1} x^{n-1} + \cdots + a_0.
- The roots of f(x)f(x) are the solutions to the equation f(x)=0f(x) = 0.
2. Splitting Field
- The splitting field LL of f(x)f(x) over KK is the smallest field extension of KK that contains all the roots of f(x)f(x).
- If f(x)f(x) has degree nn, the splitting field LL will be an extension of KK with a degree that divides n!n!.
3. Automorphisms
- An automorphism of a field LL is a bijective map from LL to itself that preserves addition and multiplication.
- The automorphisms of LL that fix KK form a group under composition.
4. Galois Group
- The Galois group Gal(L/K)\text{Gal}(L/K) of the polynomial f(x)f(x) is the group of all automorphisms of LL that fix every element of KK.
Steps to Determine the Galois Group
- Find the Roots: Determine the roots of the polynomial f(x)f(x). This can be done exactly for polynomials of degree 2, 3, and 4, but for higher degrees, it might require numerical or symbolic methods.
- Construct the Splitting Field: Identify the splitting field LL of the polynomial over the base field KK.
- Determine Automorphisms: Identify all automorphisms of the splitting field that fix the base field.
- Form the Group: The set of these automorphisms forms the Galois group, denoted Gal(L/K)\text{Gal}(L/K).
Examples
1. Quadratic Polynomial
Consider f(x)=x2−2f(x) = x^2 – 2 over Q\mathbb{Q}:
- The roots are ±2\pm \sqrt{2}.
- The splitting field is Q(2)\mathbb{Q}(\sqrt{2}).
- The Galois group consists of two elements: the identity automorphism and the automorphism sending 2\sqrt{2} to −2-\sqrt{2}.
- Thus, Gal(Q(2)/Q)≅Z/2Z\text{Gal}(\mathbb{Q}(\sqrt{2})/\mathbb{Q}) \cong \mathbb{Z}/2\mathbb{Z}.
2. Cubic Polynomial
Consider f(x)=x3−2f(x) = x^3 – 2 over Q\mathbb{Q}:
- The roots are 23,23ω,23ω2\sqrt[3]{2}, \sqrt[3]{2}\omega, \sqrt[3]{2}\omega^2, where ω\omega is a primitive cube root of unity.
- The splitting field is Q(23,ω)\mathbb{Q}(\sqrt[3]{2}, \omega).
- The Galois group has order 6 and is isomorphic to S3S_3, the symmetric group on 3 elements.
Importance of the Galois Group
- Solvability by Radicals: A polynomial is solvable by radicals if and only if its Galois group is a solvable group.
- Field Extensions: The structure of the Galois group provides information about the intermediate fields between KK and LL.
- Symmetry: The Galois group reflects the symmetries of the roots of the polynomial and helps in understanding the nature of the solutions.