Algebraic closure

• The fundamental theorem of algebra states that the algebraic closure of the field of real numbers is the field of complex numbers.
• The algebraic closure of the field of rational numbers is the field of algebraic numbers.
• There are many countable algebraically closed fields within the complex numbers, and strictly containing the field of algebraic numbers; these are the algebraic closures of transcendental extensions of the rational numbers, e.g. the algebraic closure of Q(π).
• For a finite field of prime power order q, the algebraic closure is a countably infinite field that contains a copy of the field of order qⁿ for each positive integer n (and is in fact the union of these copies).^[6]

Let ${\displaystyle S=\{f_{\lambda }\mid \lambda \in \Lambda \}}$  be the set of all monic irreducible polynomials in ${\displaystyle K[x]}$ . For each ${\displaystyle f_{\lambda }\in S}$ , introduce new variables ${\displaystyle u_{\lambda ,1},\ldots ,u_{\lambda ,d}}$  where ${\displaystyle d={\rm {degree}}(f_{\lambda })}$ . Let ${\displaystyle R}$  be the polynomial ring over ${\displaystyle K}$  generated by ${\displaystyle u_{\lambda ,i}}$  for all ${\displaystyle \lambda \in \Lambda }$  and all ${\displaystyle i\leq {\rm {degree}}(f_{\lambda }).}$  Write

${\displaystyle f_{\lambda }-\prod _{i=1}^{d}(x-u_{\lambda ,i})=\sum _{j=0}^{d-1}r_{\lambda ,j}\cdot x^{j}\in R[x]}$ 

with ${\displaystyle r_{\lambda ,j}\in R}$ . Let ${\displaystyle I}$  be the ideal in ${\displaystyle R}$  generated by the ${\displaystyle r_{\lambda ,j}}$ . Since ${\displaystyle I}$  is strictly smaller than ${\displaystyle R}$ , Zorn's lemma implies that there exists a maximal ideal ${\displaystyle M}$  in ${\displaystyle R}$  that contains ${\displaystyle I}$ . The field ${\displaystyle K_{1}=R/M}$  has the property that every polynomial ${\displaystyle f_{\lambda }}$  with coefficients in ${\displaystyle K}$  splits as the product of ${\displaystyle x-(u_{\lambda ,i}+M),}$  and hence has all roots in ${\displaystyle K_{1}}$ . In the same way, an extension ${\displaystyle K_{2}}$  of ${\displaystyle K_{1}}$  can be constructed, etc. The union of all these extensions is the algebraic closure of ${\displaystyle K}$ , because any polynomial with coefficients in this new field has its coefficients in some ${\displaystyle K_{n}}$  with sufficiently large ${\displaystyle n}$ , and then its roots are in ${\displaystyle K_{n+1}}$ , and hence in the union itself.

It can be shown along the same lines that for any subset ${\displaystyle S}$  of ${\displaystyle K[x]}$ , there exists a splitting field of ${\displaystyle S}$  over ${\displaystyle K}$ .

An algebraic closure K^alg of K contains a unique separable extension K^sep of K containing all (algebraic) separable extensions of K within K^alg. This subextension is called a separable closure of K. Since a separable extension of a separable extension is again separable, there are no finite separable extensions of K^sep, of degree > 1. Saying this another way, K is contained in a separably-closed algebraic extension field. It is unique (up to isomorphism).^[7]

The separable closure is the full algebraic closure if and only if K is a perfect field. For example, if K is a field of characteristic p and if X is transcendental over K, ${\displaystyle K(X)({\sqrt[{p}]{X}})\supset K(X)}$  is a non-separable algebraic field extension.

In general, the absolute Galois group of K is the Galois group of K^sep over K.^[8]

• Puiseux expansion
• Complete field

• Kaplansky, Irving (1972). Fields and rings. Chicago lectures in mathematics (Second ed.). University of Chicago Press. ISBN 0-226-42451-0. Zbl 1001.16500.
• McCarthy, Paul J. (1991). Algebraic extensions of fields (Corrected reprint of the 2nd ed.). New York: Dover Publications. Zbl 0768.12001.