Imaginary quadratic number field: Difference between revisions

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===Norm-Euclidean imaginary quadratic number fields===
===Norm-Euclidean imaginary quadratic number fields===


{{further|[[Classification of norm-Euclidean imaginary quadratic number fields]], [[Euclidean equals norm-Euclidean for imaginary quadratic number field]]}}
{{further|[[Classification of norm-Euclidean imaginary quadratic integer rings]], [[Euclidean equals norm-Euclidean for imaginary quadratic integer ring]]}}


A [[norm-Euclidean number field]] is a number field whose [[ring of integers in a number field|ring of integers]] has the property that the restriction of the [[algebraic norm in a number field|algebraic norm]] to the nonzero elements of this ring give a [[Euclidean norm]] on this ring.
A [[norm-Euclidean number field]] is a number field whose [[ring of integers in a number field|ring of integers]] has the property that the restriction of the [[algebraic norm in a number field|algebraic norm]] to the nonzero elements of this ring give a [[Euclidean norm]] on this ring.

Revision as of 02:33, 24 January 2009

This article defines a number field property: a property that can be evaluated for a number field

Definition

An imaginary quadratic number field is a number field obtained as a quadratic extension of the field of rational numbers by the squareroot of a negative square-free number. In other words, it is of the form Q[D] where D<0.

Relation with other properties

Weaker properties

Facts

There are two qualitatively different kinds of imaginary quadratic number fields: those where D1mod4 and where D1mod4. When D1mod4, the ring of integers is:

Z[1+D2]

whereas when D1mod4, the ring of integers is:

Z[D].

Norm-Euclidean imaginary quadratic number fields

Further information: Classification of norm-Euclidean imaginary quadratic integer rings, Euclidean equals norm-Euclidean for imaginary quadratic integer ring

A norm-Euclidean number field is a number field whose ring of integers has the property that the restriction of the algebraic norm to the nonzero elements of this ring give a Euclidean norm on this ring.

The norm-Euclidean imaginary quadratic number fields are those corresponding to values of D in the set:

{11,7,3,2,1}.

It turns out that for an imaginary quadratic number field, the ring of integers is norm-Euclidean if and only if it is Euclidean.

Imaginary quadratic number fields whose ring of integers is a unique factorization domain

The following are the values of D for which the imaginary quadratic number field Q[D] is a principal ideal domain, or equivalently, is a unique factorization domain:

{163,67,43,19,11,7,3,2,1}.