Separators of Ideals in Multiplicative Semigroups of Unique Factorization Domains

Abstract

In this paper we show that if I is an ideal of a commutative semigroup C such that the separator SepI of I is not empty then the factor semigroup S=C/PI (PI is the principal congruence on C defined by I) satisfies Condition (*): S is a commutative monoid with a zero; The annihilator A(s) of every non identity element s of S contains a non zero element of S; A(s)=A(t) implies s=t for every s, t∈ S. Conversely, if α is a congruence on a commutative semigroup C such that the factor semigroup S=C/α satisfies Condition (*) then there is an ideal I of C such that α =PI. Using this result for the multiplicative semigroup Dmult of a unique factorization domain D, we show that PJ(m)=τ m for every nonzero element m∈ D, where J(m) denotes the ideal of D generated by m, and τ m is the relation on D defined by (a, b)∈ τ m if and only if gcd(a, m) gcd(b, m) ( is the associate congruence on Dmult). We also show that if a is a nonzero element of a unique factorization domain D then d(a)=|D'/PJ([a])|, where d(a) denotes the number of all non associated divisors of a, D'=D/, and [a] denotes the -class of Dmult containing a. As an other application, we show that if d is one of the integers -1, -2, -3, -7, -11, -19, -43, -67, -163 then, for every nonzero ideal I of the ring R of all algebraic integers of an imaginary quadratic number field Q[ d], there is a nonzero element m of R such that PI=τ m.