Extension and contraction of ideals

In commutative algebra, the extension and contraction of ideals are operations performed on sets of ideals.

Extension of an ideal

Let A and B be two commutative rings with unity, and let f : AB be a (unital) ring homomorphism. If \mathfrak{a} is an ideal in A, then f(\mathfrak{a}) need not be an ideal in B (e.g. take f to be the inclusion of the ring of integers Z into the field of rationals Q). The extension \mathfrak{a}^e of \mathfrak{a} in B is defined to be the ideal in B generated by f(\mathfrak{a}). Explicitly,

\mathfrak{a}^e = \Big\{ \sum y_if(x_i) : x_i \in \mathfrak{a}, y_i \in B \Big\}

Contraction of an ideal

If \mathfrak{b} is an ideal of B, then f^{-1}(\mathfrak{b}) is always an ideal of A, called the contraction \mathfrak{b}^c of \mathfrak{b} to A.

Properties

Assuming f : AB is a unital ring homomorphism, \mathfrak{a} is an ideal in A, \mathfrak{b} is an ideal in B, then:

On the other hand, if f is surjective and  \mathfrak{a} \supseteq \mathop{\mathrm{ker}} f then:

Extension of prime ideals in number theory

Let K be a field extension of L, and let B and A be the rings of integers of K and L, respectively. Then B is an integral extension of A, and we let f be the inclusion map from A to B. The behaviour of a prime ideal \mathfrak{a} = \mathfrak{p} of A under extension is one of the central problems of algebraic number theory.

See also

References

    This article is issued from Wikipedia - version of the Tuesday, June 09, 2015. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.