Extensions of <math><mi>ℚ</mi></math>

Extensions of $ℚ$

Arun Ram
Department of Mathematics and Statistics
University of Melbourne
Parkville, VIC 3010 Australia
aram@unimelb.edu.au

Last update: 02 February 2012

Extensions of $ℚ$

An algebraic number is an element of $\overline{ℚ}$ the algebraic closure of $ℚ$ .
An algebraic number field is a finite extension of $ℚ$ .
Let $f (x) \in ℚ [x] .$ The discriminant of $f (x)$ is $D^{2} where D = \prod_{1 \leq i < j \leq k} (α_{i} - α_{j}),$ where $α_{1} ... α_{k} \in \overline{ℚ}$ are such that $f (x) = (x - α_{1}) \dots (x - α_{k}) \in \overline{ℚ} [x] .$

Let $𝔼$ be the splitting field of $f (x) \in ℚ [x] .$ Note that if $σ \in Gal (𝔼 / 𝔽)$ then $σ$ is a permutation of the roots and $σ \cdot D = {(- 1)}^{l (σ)} D .$ Thus $D^{2}$ is always fixed by $σ$ and so $D^{2} \in 𝔽 .$ If $D \notin 𝔽$ then $ℚ (D)$ is a degree two extension of $ℚ$ since the minimal polynomial of $D$ is $x^{2} - D^{2} .$ If $D \in ℚ$ then $Gal (𝔼 / ℚ) \subseteq A_{n},$ the alternating group.

Example 1. If $f (x) = x^{2} + b x + c \in ℚ [x]$ and $f (x) = x^{2} + b x + c = (x - α_{1}) (x - α_{2}) \in \overline{ℚ} [x]$ then $ℚ (α_{1}) = ℚ (α_{2}) since α_{1} = b - α_{1} .$ If $σ \in Gal (ℚ (α_{1}) / ℚ)$ is the element given by $σ (α_{1}) = α_{2} then σ (α_{2}) = α_{1},$ since $α_{2} + σ (α_{2}) = σ (α_{1} + α_{2}) = σ (b) = b = α_{1} + α_{2} .$ So $Gal (ℚ (α_{1}) / ℚ) = {1, σ} ≅ ℤ / 2 ℤ = S_{2} .$ Now the discriminant $D^{2} = b^{2} - 4 c \in ℚ$ and $D = \sqrt{b^{2} - 4 c} \in ℚ (α_{1}) .$ So $ℚ (α_{1}) = ℚ (D) and σ (D) = - D .$

Example 2. Let $f (x) = x^{3} + a_{2} x^{2} + a_{1} x + a_{0} = 0 .$ Change variable $x = y - \frac{a_{2}}{3} .$ Then $f (x) = y^{3} - a_{2} y^{2} + (\frac{3 y a_{2}^{2}}{9}) - \frac{a_{2}^{3}}{27} + a_{2} y^{2} - (\frac{2 a_{2} x^{2}}{3}) y + \frac{a_{2}^{3}}{9} + a_{1} y - \frac{a_{1} a_{2}}{3} + a_{0} = 0 .$ So assume $f (x) = x^{3} + b x + c$ and let $𝔼$ be the splitting field of $f (x)$ . If $f (x)$ is separable and irreducible then $D^{2} = - 4 b^{3} - 27 c^{2} and Gal (𝔼 / 𝔽) = {\begin{cases} S_{3}, & if D \notin 𝔽, \\ ℤ / 3 ℤ, & if D \in 𝔽 . \end{cases}$ If $f (x) = x^{3} + b x + c = (x - α_{1}) (x - α_{2}) (x - α_{3})$ then $\begin{array}{rcl} e_{3} & = & α_{1} α_{2} α_{3} = - c, \\ e_{2} & = & α_{1} α_{2} + α_{2} α_{3} + α_{1} α_{3} = b, \\ e_{1} & = & α_{1} + α_{2} + α_{3} . \end{array}$ $\begin{array}{cccccccc} ℚ (α_{1}, α_{2}, α_{3}) & {1} \\ ℚ (α_{1}) & ℚ (α_{2}) & ℚ (α_{3}) & {1, (1,3)} & {1, (23)} & {1, (23)} \\ ℚ (D) & A_{3} \\ ℚ & S_{3} \end{array}$ A concrete example is $f (x) = x^{3} - 2$ which has roots $2^{1 / 3}, ω 2^{1 / 3}, ω^{2} 2^{1 / 3},$ where $ω$ is a primitive cube root of unity and $Gal (𝔼 / ℚ) ≅ S_{3} .$ $\begin{array}{cc} 𝔼 = ℚ (2^{\frac{1}{3}}, ω) & {1} \\ | & | \\ ℚ (2^{\frac{1}{3}}) & ⟨ σ ⟩ ≅ ℤ / 3 ℤ \\ | & | \\ ℚ & ⟨σ, τ| σ^{3} = 1, τ^{2} = 1, σ τ = τ σ^{- 1}⟩ ≅ S_{3} \end{array}$ Examples of the two cases are $\begin{array}{rcl} f (x) = x^{3} - 3 x + 1 & which has & D^{2} = 81, and \\ f (x) = x^{3} + 3 x + 1 & which has & D^{2} = - 135, \end{array}$ and roots of these polynomials are ????

Example 3. Let $f (x) = x^{4} - 2$ which has roots $2^{\frac{1}{4}}, i 2^{\frac{1}{4}}, - 2^{\frac{1}{4}}, - i 2^{\frac{1}{4}} \in ℂ,$ and let $𝔼$ be the splitting field of $f (x)$ . Then $Gal (𝔼 / 𝔽) = ⟨σ, τ| σ^{3} = 1, τ^{2} = 1, σ τ = τ σ^{- 1}⟩$ is the dihedral group of order 8. $\begin{array}{cccccccccc} ℚ (2^{\frac{1}{4}}, i) \\ ℚ ((1 - i) 2^{\frac{1}{4}}) & ℚ ((1 + i) 2^{\frac{1}{4}}) & ℚ (\sqrt{2}, i) & ℚ (i 2^{\frac{1}{4}}) & ℚ (2^{\frac{1}{4}}) & ⟨σ^{3} τ⟩ & ⟨σ τ⟩ & ⟨σ^{2}⟩ & ⟨σ^{2} τ⟩ & ⟨τ⟩ \\ ℚ (i \sqrt{2}) & ℚ (i) & ℚ (\sqrt{2}) & ⟨σ τ, σ^{2}⟩ & ⟨σ^{2}⟩ & ⟨τ, σ^{2}⟩ \\ ℚ & ⟨σ, τ⟩ \end{array}$

Example 4. Let $f (x) = x^{4} + 1$ which has roots $ω, ω^{3}, ω^{5}, ω^{7}$ where $ω = e^{\frac{2 π i}{8}} \in ℂ,$ and let $𝔼$ be the splitting field of $f (x)$ . Then $Gal (𝔼 / ℚ) = ⟨σ, τ| σ^{2} = 1, τ^{2} = 1, σ τ = τ σ⟩ ≅ ℤ / 2 ℤ \times ℤ / 2 ℤ$ is the Klein four group.
Let $a, b \in ℚ$ and consider the extension $ℚ (\sqrt{a}, \sqrt{b})$ which is the splitting field of $f (x) = (x^{2} - a) (x^{2} - b) .$ Then $Gal (ℚ (\sqrt{a}, \sqrt{b}) / ℚ) = ⟨σ, τ| σ^{2} = 1, τ^{2} = 1, σ τ = τ σ⟩ ≅ ℤ / 2 ℤ \times ℤ / 2 ℤ$ is the Klein four group with $\begin{array}{ccc} σ (\sqrt{a}) = - \sqrt{a}, & τ (\sqrt{a}) = \sqrt{a}, \\ and \\ σ (\sqrt{b}) = \sqrt{b}, & τ (\sqrt{b}) = - \sqrt{b}, \end{array}$
$\begin{array}{cccccc} ℚ (\sqrt{a}, \sqrt{b}) & {1} \\ ℚ (\sqrt{b}) & ℚ (\sqrt{a}) & ℚ (\sqrt{a} \sqrt{b}) & ⟨ σ τ ⟩ & ⟨ σ ⟩ & ⟨ τ ⟩ \\ ℚ & ⟨σ, τ⟩ \end{array}$ Note that $ℚ (\sqrt{a}, \sqrt{b})$ since ${(\sqrt{a} + \sqrt{b})}^{2} = a + 2 \sqrt{a} \sqrt{b} + b^{2} \in ℚ (\sqrt{a} + \sqrt{b})$ and so $(\sqrt{a} \sqrt{b}) (\sqrt{a} + \sqrt{b}) = (a \sqrt{b} + b \sqrt{a}) \in ℚ (\sqrt{a} + \sqrt{b}) .$ So $(b - a) \sqrt{a} \in ℚ (\sqrt{a} + \sqrt{b}) .$

Example 5. Let $f (x) = x^{n} - 1$ which has roots $ω ω^{2} ... ω^{n - 1} \in ℂ$ where $ω = e^{\frac{2 π i}{n}},$ and let $𝔼$ be the splitting field of $f (x)$ . Then $Gal (𝔼 / ℚ) ≅ {(ℤ / n ℤ)}^{*} and | {(ℤ / n ℤ)}^{*} | = φ (n),$ where $φ (n)$ is Euler's phi function.

Example 6. Assume $𝔽$ contains a primitive $n^{th}$ root of unity and let $𝔼$ be a finite Galois extension of $𝔽$ . Then $Gal (𝔼 / 𝔽) ≅ ℤ / n ℤ if and only if 𝔼 is the splitting field of an irreducible x^{n} - b for some b \in 𝔽 .$

Example 7. Assume $𝔼 = 𝔽 (x_{1} ... x_{n})$ and $𝕂 = 𝔽 (e_{1} ... e_{n}),$ where $e_{1} e_{2} ... e_{n}$ are the elementary symmetric functions. Then $𝔼 is the splitting field of f (x) = \prod_{i = 1}^{n} (x - x_{i}) \in 𝕂 [x] and Gal (𝔼 / 𝕂) ≅ S_{n} .$

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Extensions of ℚ

Extensions of ℚ

Notes and References

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Extensions of $ℚ$

Extensions of $ℚ$