Dedekind domain: Difference between revisions

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A Dedekind domain is a Noetherian domain $o$ , integrally closed in its field of fractions, so that every prime ideal is maximal.

These axioms are sufficient for ensuring that every ideal of $o$ that is not $(0)$ or $(1)$ can be written as a finite product of prime ideals in a unique way (up to a permutation of the terms of the product). In fact, this property has a natural extension to the fractional ideals of the field of fractions of $o$ .

This product extends to the set of fractional ideals of the field $K=Frac(o)$ (i.e., the nonzero finitely generated $o$ -submodules of $K$ ).

Useful properties

Every principal ideal domain is a unique factorization domain, but the converse is not true in general. However, these notions are equivalent for Dedekind domains; that is, a Dedekind domain $A$ is a principal ideal domain if and only if it is a unique factorization domain.
The localization of a Dedekind domain at a non-zero prime ideal is a principal ideal domain, which is either a field or a discrete valuation ring.

Examples

The ring $\mathbb {Z}$ is a Dedekind domain.
Let $K$ be an algebraic number field. Then the integral closure $o_{K}$ of $\mathbb {Z}$ in $K$ is again a Dedekind domain. In fact, if $o$ is a Dedekind domain with field of fractions $K$ , and $L/K$ is a finite extension of $K$ and $O$ is the integral closure of $o$ in $L$ , then $O$ is again a Dedekind domain.

==Finitely generated modules over a Dedekind domain==

@@ Line 1: / Line 1: @@
-==Definition==
+{{subpages}}
+A '''Dedekind domain''' is a [[Noetherian domain]] <math>o</math>, integrally closed in its [[field of fractions]], so that every [[prime ideal]] is maximal.
-A ''Dedekind domain'' is a Noetherian domain <math>o</math>, integrally closed in its field of fractions, so that every prime ideal is maximal.
+These axioms are sufficient for ensuring that every [[ideal (mathematics)|ideal]] of <math>o</math> that is not <math>(0)</math> or <math>(1)</math> can be written as a finite product of prime ideals in a unique way (up to a permutation of the terms of the product). In fact, this property has a natural extension to the fractional ideals of the field of fractions of <math>o</math>.
-These axioms are sufficient for ensuring that every ideal of <math>o</math> that is not <math>(0)</math> or <math>(1)</math> can be written as a finite product of prime ideals in a unique way (up to a permutation of the terms of the product).
+This product extends to the set of fractional ideals of the field <math>K=Frac(o)</math> (i.e., the nonzero finitely generated <math>o</math>-submodules of <math>K</math>).
-This product extends to the set of fractional ideals of the field <math>K=Frac(o)</math> (i.e., the nonzero finitely generated <math>o</math>-submodules of <math>K</math>).
+==Useful properties==
-==Useful Properties==
+#Every [[principal ideal domain]] is a [[unique factorization domain]], but the converse is not true in general. However, these notions are equivalent for Dedekind domains; that is, a Dedekind domain <math>A</math> is a principal ideal domain if and only if it is a unique factorization domain.
+#The [[localization]] of a Dedekind domain at a non-zero prime ideal is a principal ideal domain, which is either a [[field (mathematics)|field]] or a [[discrete valuation ring]].
-#Every principal ideal domain is a unique factorization domain, but the converse is not true in general. However, these notions are equivalent for Dedekind domains.
-#The localization of a Dedekind domain at a non-zero prime ideal is a principal ideal domain, which is either a field or a discrete valuation ring.
 ==Examples==
 #The ring <math>\mathbb{Z}</math> is a Dedekind domain.
-#Let <math>K</math> be a [[number field]]. Then the integral closure <math>o_K</math>of <math>\mathbb{Z}</math> in <math>K</math> is again a Dedekind domain. In fact, if <math>o</math> is a Dedekind domain with field of fractions <math>K</math>, and <math>L/K</math> is a finite extension of <math>K</math> and <math>O</math> is the integral closure of <math>o</math> in <math>L</math>, then <math>O</math> is again a Dedekind domain.
+#Let <math>K</math> be an [[algebraic number field]]. Then the integral closure <math>o_K</math>of <math>\mathbb{Z}</math> in <math>K</math> is again a Dedekind domain. In fact, if <math>o</math> is a Dedekind domain with field of fractions <math>K</math>, and <math>L/K</math> is a finite extension of <math>K</math> and <math>O</math> is the integral closure of <math>o</math> in <math>L</math>, then <math>O</math> is again a Dedekind domain.
-==References==
-* Neukirch, Jürgen (1999). ''Algebraic Number Theory'', , ISBN 3-540-65399-6.
+==Finitely generated modules over a Dedekind domain==[[Category:Suggestion Bot Tag]]
-*{{cite book
- | first      = Jürgen
- | last       = Neukirch
- | coauthors  =
- | year       = 1999
- | title      = Algebraic Number Theory
- | edition    =
- | publisher  = Springer-Verlag
- | id         = ISBN 3-540-65399-6
-}}

Dedekind domain: Difference between revisions

Latest revision as of 11:01, 5 August 2024

Useful properties

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