On the Arithmetic of Power Monoids and Sumsets in Cyclic Groups

Abstract

Let H be a multiplicatively written monoid with identity 1H (in particular, a group). We denote by P fin,×(H) the monoid obtained by endowing the collection of all finite subsets of H containing a unit with the operation of setwise multiplication (X,Y) \xy: x ∈ X, y ∈ Y\; and study fundamental features of the arithmetic of this and related structures, with a focus on the submonoid, Pfin,1(H), of Pfin,×(H) consisting of all finite subsets X of H with 1H ∈ X. Among others, we prove that Pfin,1(H) is atomic (i.e., each non-unit is a product of irreducibles) iff 1H x2 x for every x ∈ H \1H\. Then we obtain that Pfin,1(H) is BF (i.e., it is atomic and every element has factorizations of bounded length) iff H is torsion-free; and show how to transfer these conclusions to Pfin,×(H). Next, we introduce "minimal factorizations" to account for the fact that monoids may have non-trivial idempotents, in which case standard definitions from Factorization Theory degenerate. Accordingly, we obtain conditions for Pfin,×(H) to be BmF (meaning that each non-unit has minimal factorizations of bounded length); and for Pfin,1(H) to be BmF, HmF (i.e., a BmF-monoid where all the minimal factorizations of a given element have the same length), or minimally factorial (i.e., a BmF-monoid where each element has an essentially unique minimal factorization). Finally, we prove how to realize certain intervals as sets of minimal lengths in Pfin,1(H). Many proofs come down to considering sumset decompositions in cyclic groups, so giving rise to an intriguing interplay with Arithmetic Combinatorics.