Difference between revisions of "Galois extension"
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''of a field'' | ''of a field'' | ||
− | An [[extension of a field]] that is [[Algebraic extension|algebraic]], [[Normal extension|normal]] and [[Separable extension|separable]]. The | + | An [[extension of a field]] that is [[Algebraic extension|algebraic]], [[Normal extension|normal]] and [[Separable extension|separable]]. |
+ | The group of all automorphisms of a Galois extension $K / k$ that leave all elements of $k$ invariant is called the ''[[Galois group]]'' of | ||
+ | this extension, denoted by $\def\Gal{\textrm{Gal}}\Gal(K/k)$. The study of these groups is a major part of [[Galois theory]]. | ||
− | The | + | The order (number of elements) of $\Gal(K/k)$ is equal to the degree of $K$ over $k$. |
− | + | To each subgroup $H$of $\Gal(K/k)$ corresponds a subfield $P$ of $K$, consisting of all elements | |
− | + | from $K$ that remain fixed under all automorphisms from $H$. Conversely, to each subfield $P\subset K$ that contains $k$ corresponds a subgroup $H$ of $\Gal(K/k)$. It consists of all automorphisms leaving each | |
− | + | element of $P$ invariant. Here, $K$ is a Galois extension of $P$ and $\Gal(K/P)=H$. The main theorem in Galois theory states that these correspondences are mutually inverse, and are therefore one-to-one | |
− | of $\Gal(K/k)$ corresponds a subfield $P$ of $K$, consisting of all elements | + | correspondences between all subgroups of $\Gal(K/k)$ and all subfields of $K$ containing $k$. In this correspondence certain "good" properties of subgroups correspond to |
− | from $K$ that remain fixed under all automorphisms from | + | the "good" properties of subfields and vice versa. Thus, a subgroup $H$ will be a normal subgroup of $\Gal(K/k)=G$ if and only if the field $P$ which corresponds to it is a Galois extension of $k$. |
− | $H$. Conversely, to each subfield $P\subset K$ that contains $k$ corresponds a | + | Moreover, $\Gal(P/k)$ is isomorphic to $G/H$. |
− | subgroup $H$ of $\Gal(K/k)$. It consists of all automorphisms leaving each | ||
− | element of $P$ invariant. Here, $K$ is a Galois extension of $P$ and | ||
− | $\Gal(K/P)=H$. The main theorem in Galois theory states that these | ||
− | correspondences are mutually inverse, and are therefore one-to-one | ||
− | correspondences between all subgroups of $\Gal(K/k)$ and all subfields of $K$ | ||
− | containing $k$. In this | ||
− | correspondence certain "good" properties of subgroups correspond to | ||
− | the "good" properties of subfields and vice versa. Thus, a subgroup | ||
− | $H$ will be a normal subgroup of $\Gal(K/k)=G$ if and only if the field $P$ | ||
− | which corresponds to it is a Galois extension of $k$. Moreover, $\Gal(P/k)$ is | ||
− | isomorphic to $G/H$. |
Revision as of 07:38, 1 January 2016
2020 Mathematics Subject Classification: Primary: 12F10 [MSN][ZBL]
of a field
An extension of a field that is algebraic, normal and separable. The group of all automorphisms of a Galois extension $K / k$ that leave all elements of $k$ invariant is called the Galois group of this extension, denoted by $\def\Gal{\textrm{Gal}}\Gal(K/k)$. The study of these groups is a major part of Galois theory.
The order (number of elements) of $\Gal(K/k)$ is equal to the degree of $K$ over $k$. To each subgroup $H$of $\Gal(K/k)$ corresponds a subfield $P$ of $K$, consisting of all elements from $K$ that remain fixed under all automorphisms from $H$. Conversely, to each subfield $P\subset K$ that contains $k$ corresponds a subgroup $H$ of $\Gal(K/k)$. It consists of all automorphisms leaving each element of $P$ invariant. Here, $K$ is a Galois extension of $P$ and $\Gal(K/P)=H$. The main theorem in Galois theory states that these correspondences are mutually inverse, and are therefore one-to-one correspondences between all subgroups of $\Gal(K/k)$ and all subfields of $K$ containing $k$. In this correspondence certain "good" properties of subgroups correspond to the "good" properties of subfields and vice versa. Thus, a subgroup $H$ will be a normal subgroup of $\Gal(K/k)=G$ if and only if the field $P$ which corresponds to it is a Galois extension of $k$. Moreover, $\Gal(P/k)$ is isomorphic to $G/H$.
Galois extension. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Galois_extension&oldid=37206