GCD domain

In mathematics, a GCD domain is an integral domain R with the property that any two non-zero elements have a greatest common divisor (GCD). Equivalently, any two non-zero elements of R have a least common multiple (LCM).[1]

A GCD domain generalizes a unique factorization domain to the non-Noetherian setting in the following sense: an integral domain is a UFD if and only if it is a GCD domain satisfying the ascending chain condition on principal ideals (and in particular if it is Noetherian).

GCD domains appear in the following chain of class inclusions:

commutative ringsintegral domainsintegrally closed domainsGCD domainsunique factorization domainsprincipal ideal domainsEuclidean domainsfieldsfinite fields

Properties

Every irreducible element of a GCD domain is prime (however irreducible elements need not exist, even if the GCD domain is not a field). A GCD domain is integrally closed, and every nonzero element is primal.[2] In other words, every GCD domain is a Schreier domain.

For every pair of elements x, y of a GCD domain R, a GCD d of x and y and a LCM m of x and y can be chosen such that dm = xy, or stated differently, if x and y are nonzero elements and d is any GCD d of x and y, then xy/d is a LCM of x and y, and vice versa. It follows that the operations of GCD and LCM make the quotient R/~ into a distributive lattice, where "~" denotes the equivalence relation of being associate elements. The equivalence between the existence of GCDs and the existence of LCMs is not a corollary of the similar result on complete lattices, as the quotient R/~ need not be a complete lattice for a GCD domain R.

If R is a GCD domain, then the polynomial ring R[X1,...,Xn] is also a GCD domain.[3]

R is a GCD domain if and only if finite intersections of its principal ideals are principal. In particular, , where is the LCM of and .

For a polynomial in X over a GCD domain, one can define its contents as the GCD of all its coefficients. Then the contents of a product of polynomials is the product of their contents, as expressed by Gauss's lemma, which is valid over GCD domains.

Examples

References

  1. Scott T. Chapman, Sarah Glaz (ed.) (2000). Non-Noetherian Commutative Ring Theory. Mathematics and Its Applications. Springer. p. 479. ISBN 0-7923-6492-9.
  2. proof
  3. Robert W. Gilmer, Commutative semigroup rings, University of Chicago Press, 1984, p. 172.
  4. Ali, Majid M.; Smith, David J. (2003), "Generalized GCD rings. II", Beiträge zur Algebra und Geometrie, 44 (1): 75–98, MR 1990985. P. 84: "It is easy to see that an integral domain is a Prüfer GCD-domain if and only if it is a Bezout domain, and that a Prüfer domain need not be a GCD-domain.".
  5. Gilmer, Robert; Parker, Tom (1973), "Divisibility Properties in Semigroup Rings", Michigan Mathematical Journal, 22 (1): 65–86, MR 342635.
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