Existence and Uniqueness of Algebraic Closures

IF 1 Q1 MATHEMATICS

Formalized Mathematics Pub Date : 2022-12-01 DOI:10.2478/forma-2022-0022

Christoph Schwarzweller

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引用次数: 3

Abstract

Summary This is the second part of a two-part article formalizing existence and uniqueness of algebraic closures, using the Mizar [2], [1] formalism. Our proof follows Artin’s classical one as presented by Lang in [3]. In the first part we proved that for a given field F there exists a field extension E such that every non-constant polynomial p ∈ F [X] has a root in E. Artin’s proof applies Kronecker’s construction to each polynomial p ∈ F [X]\F simultaneously. To do so we needed the polynomial ring F [X1, X2, ...] with infinitely many variables, one for each polynomal p ∈ F [X]\F. The desired field extension E then is F [X1, X2, …]\I, where I is a maximal ideal generated by all non-constant polynomials p ∈ F [X]. Note, that to show that I is maximal Zorn’s lemma has to be applied. In this second part this construction is iterated giving an infinite sequence of fields, whose union establishes a field extension A of F, in which every non-constant polynomial p ∈ A[X] has a root. The field of algebraic elements of A then is an algebraic closure of F. To prove uniqueness of algebraic closures, e.g. that two algebraic closures of F are isomorphic over F, the technique of extending monomorphisms is applied: a monomorphism F → A, where A is an algebraic closure of F can be extended to a monomorphism E → A, where E is any algebraic extension of F. In case that E is algebraically closed this monomorphism is an isomorphism. Note that the existence of the extended monomorphism again relies on Zorn’s lemma.

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代数闭包的存在唯一性

这是使用Mizar[2]，[1]形式主义形式化代数闭包的存在性和唯一性的两部分文章的第二部分。我们的证明遵循Lang在[3]中提出的Artin的经典证明。在第一部分中，我们证明了对于给定的域F存在一个域扩展E，使得每个非常数多项式p∈F [X]在E中都有根。Artin的证明将Kronecker构造同时应用于每个多项式p∈F [X]\F。为此，我们需要多项式环F [X1, X2，…]]有无穷多个变量，每个多项式p∈F [X]\F对应一个变量。则期望域扩展E为F [X1, X2，…]\I，其中I是由所有非常多项式p∈F [X]生成的极大理想。注意，为了证明I是最大值，必须应用佐恩引理。在第二部分中，迭代该构造，给出一个无限域序列，其并建立F的域扩展a，其中每个非常多项式p∈a [X]都有一个根。为了证明代数闭包的唯一性，例如F的两个代数闭包在F上是同构的，应用了扩展单态的技术:一个单态F→A，其中A是F的代数闭包，可以推广到一个单态E→A，其中E是F的任意代数扩展，当E是代数闭包时，这个单态是同构的。注意，扩展单态的存在性同样依赖于佐恩引理。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Formalized Mathematics MATHEMATICS-

自引率

0.00%

发文量

审稿时长

10 weeks

期刊介绍： Formalized Mathematics is to be issued quarterly and publishes papers which are abstracts of Mizar articles contributed to the Mizar Mathematical Library (MML) - the basis of a knowledge management system for mathematics.