Factorization in monoids and rings

Abstract

Let H× be the group of units of a multiplicatively written monoid H. We say H is acyclic if xyz y for all x, y, z ∈ H with x H× or z H×; unit-cancellative if yx x xy for all x, y ∈ H with y H×; f.g.u. if there is a finite set A ⊂eq H such that every non-unit of H is a finite product of elements of the form uav with u, v ∈ H× and a ∈ A; l.f.g.u. if, for each x ∈ H, the smallest divisor-closed submonoid of H containing x is f.g.u; and atomic if every non-unit can be written as a finite product of atoms, where an atom is a non-unit that does not factor into a product of two non-units. We generalize to l.f.g.u. or acyclic l.f.g.u. monoids a few results so far only known for unit-cancellative l.f.g.u. commutative monoids (cancellative monoids are unit-cancellative, and a commutative monoid is unit-cancellative if and only if it is acyclic). In particular, we prove the following: If H is an atomic l.f.g.u. monoid, then every non-unit has only finitely many factorizations (into atoms) that are "minimal" and "pairwise non-equivalent" (with respect to some naturally defined relations on the free monoid over the "alphabet" of atoms). If H is an acyclic l.f.g.u. monoid, then it is atomic; and moreover, each element has only finitely many "pairwise non-equivalent" factorizations if we additionally assume H to be commutative.