Separable extension
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In mathematics, a field extension L/K is separable if it can be generated by adjoining to K a set each of whose elements is a root of a separable polynomial over K. In that case, each β in L has a separable minimal polynomial over K.
The condition of separability is central in Galois theory. A perfect field is one for which all finite (equivalently, algebraic) extensions are separable. There exists a simple criterion for perfectness: a field F is perfect if and only if
- F has characteristic 0, or
- F has a nonzero characteristic p, and every element of F has a p-th root in F.
Equivalently, the second condition says that the Frobenius endomorphism of F, 
, is an automorphism.
In particular, all fields of characteristic 0, and all finite fields are perfect. This means that the separability condition can be assumed in many contexts. The effects of inseparability (necessarily for infinite K of characteristic p) can be seen in the primitive element theorem, and for the tensor product of fields.
Given a finite extension L/K of fields, there is a smallest subfield M of L containing K such that L is a separable extension of M. When L = M the extension L/K is called a purely inseparable extension. In general an algebraic extension factors as a purely inseparable extension of a separable extension, since the compositum of a family of separable extensions is again separable.
Purely inseparable extensions do occur for quite natural reasons, for example in algebraic geometry in characteristic p. If K is a field of characteristic p, and V an algebraic variety over K of dimension > 0, consider the function field K(V) and its subfield K(V)p of p-th powers. This is always a purely inseparable extension. Such extensions occur as soon as one looks at multiplication by p on an elliptic curve over a finite field of characteristic p.
In dealing with non-perfect fields K, one introduces the separable closure Ksep inside an algebraic closure, which is the largest separable subextension of Kalg/K. Then Galois theory can be carried out inside Ksep.
[edit] References
- Hungerford, Thomas (1974). Algebra. Springer. ISBN 0-38-790518-9.
- Lang, Serge (2002). Algebra. Springer. ISBN 0-387-95385-X.
- Silverman, Joeseph (1993). The Arithmetic of Elliptic Curves. Springer. ISBN 0-38-796203-4.
