The Separating Noether Number of Finite Abelian Groups
Abstract
For a finite abelian group G, let βsep(G) denote its separating Noether number. We determine βsep(G) exactly for every finite abelian group G Cn1 ·s Cnr with 1<n1 ·s nr. If r=2s-1, then βsep(G)=ns+ns+1+·s+nr, whereas if r=2s, then βsep(G)=nsp1+ns+1+·s+nr, where p1 denotes the smallest prime divisor of n1. Our proof is additive-combinatorial in nature. It avoids the Davenport-equality assumption D(nsG)=D*(nsG) used in previous works. The key ingredients are a geometric reduction of auxiliary sequences via the novel construction of geodesic surrogates, alongside a uniform lifting procedure for relation groups. As an application, we prove that if r 2, then every extremal separating atom A over G0 with |G0| r+1 satisfies |(A)|=|G0|=r+1. Equivalently, the conjectured support conclusion of Schefler, Zhao, and Zhong holds for all finite abelian groups of rank at least 2. By contrast, the rank-1 case is exceptional: for cyclic groups, the analogous conjectural conclusion is false.
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