Galois extension

Last updated May 04, 2024

In mathematics, a Galois extension is an algebraic field extension E/F that is normal and separable;^[1] or equivalently, E/F is algebraic, and the field fixed by the automorphism group Aut(E/F) is precisely the base field F. The significance of being a Galois extension is that the extension has a Galois group and obeys the fundamental theorem of Galois theory.^{[lower-alpha 1]}

Characterization of Galois extensions

An important theorem of Emil Artin states that for a finite extension $E/F,$ each of the following statements is equivalent to the statement that $E/F$ is Galois:

$E/F$ is a normal extension and a separable extension.
$E$ is a splitting field of a separable polynomial with coefficients in $F.$
$|\!\operatorname {Aut} (E/F)|=[E:F],$ that is, the number of automorphisms equals the degree of the extension.

Other equivalent statements are:

Every irreducible polynomial in $F[x]$ with at least one root in $E$ splits over $E$ and is separable.
$|\!\operatorname {Aut} (E/F)|\geq [E:F],$ that is, the number of automorphisms is at least the degree of the extension.
$F$ is the fixed field of a subgroup of $\operatorname {Aut} (E).$
$F$ is the fixed field of $\operatorname {Aut} (E/F).$
There is a one-to-one correspondence between subfields of $E/F$ and subgroups of $\operatorname {Aut} (E/F).$

An infinite field extension $E/F$ is Galois if and only if $E$ is the union of finite Galois subextensions $E_{i}/F$ indexed by an (infinite) index set $I$ , i.e. $E=\bigcup _{i\in I}E_{i}$ and the Galois group is an inverse limit $\operatorname {Aut} (E/F)=\varprojlim _{i\in I}{\operatorname {Aut} (E_{i}/F)}$ where the inverse system is ordered by field inclusion $E_{i}\subset E_{j}$ .^[4]

Examples

There are two basic ways to construct examples of Galois extensions.

Take any field $E$ , any finite subgroup of $\operatorname {Aut} (E)$ , and let $F$ be the fixed field.
Take any field $F$ , any separable polynomial in $F[x]$ , and let $E$ be its splitting field.

Adjoining to the rational number field the square root of 2 gives a Galois extension, while adjoining the cubic root of 2 gives a non-Galois extension. Both these extensions are separable, because they have characteristic zero. The first of them is the splitting field of $x^{2}-2$ ; the second has normal closure that includes the complex cubic roots of unity, and so is not a splitting field. In fact, it has no automorphism other than the identity, because it is contained in the real numbers and $x^{3}-2$ has just one real root. For more detailed examples, see the page on the fundamental theorem of Galois theory.

An algebraic closure ${\bar {K}}$ of an arbitrary field $K$ is Galois over $K$ if and only if $K$ is a perfect field.

Notes

↑ See the article Galois group for definitions of some of these terms and some examples.

Citations

↑ Lang 2002, p. 262.
↑ Lang 2002, p. 264, Theorem 1.8.
↑ Milne 2022, p. 40f, ch. 3 and 7.
↑ Milne 2022, p. 102, example 7.26.

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References

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Artin, Emil (1998) [1944]. Galois Theory. Edited and with a supplemental chapter by Arthur N. Milgram. Mineola, NY: Dover Publications. ISBN 0-486-62342-4. MR 1616156.
Bewersdorff, Jörg (2006). Galois theory for beginners. Student Mathematical Library. Vol. 35. Translated from the second German (2004) edition by David Kramer. American Mathematical Society. doi:10.1090/stml/035. ISBN 0-8218-3817-2. MR 2251389. S2CID 118256821.
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Funkhouser, H. Gray (1930). "A short account of the history of symmetric functions of roots of equations". American Mathematical Monthly. 37 (7). The American Mathematical Monthly, Vol. 37, No. 7: 357–365. doi:10.2307/2299273. JSTOR 2299273.
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[2] See the article Galois group for definitions of some of these terms and some examples.

[FOOTNOTELang2002262-1] Lang 2002, p. 262.

[FOOTNOTELang2002264Theorem_1.8-3] Lang 2002, p. 264, Theorem 1.8.

[FOOTNOTEMilne202240fch._3_and_7-4] Milne 2022, p. 40f, ch. 3 and 7.

[FOOTNOTEMilne2022102example_7.26-5] Milne 2022, p. 102, example 7.26.

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