Higher Commutativity in Finite Groups, Rigidity, Extremal bounds, and Heisenberg-Type Families

Abstract

For a finite group G and an integer r 2 let Pr(G):=|Hom( Zr,G)||G|r, where ( Zr,G) is the set of pairwise commuting r-tuples in G. This paper studies rigidity and extremal behavior of the hierarchy \Pr(G)\r2, together with a low-rank representation-theoretic / TQFT counting bridge. The first main direction is cyclic-index rigidity: for groups with an abelian normal subgroup A and cyclic quotient of order ω, under a natural fixed-subgroup hypothesis we prove the exact all-rank formula Pr(G)=1ωr+(1-1ωr)(|A Z(G)||A|)r-1, which yields gap and rigidity statements for non-abelian abelian extensions of prime index. The second main direction is the class-2 exponent-p world. We develop a symplectic reduction, obtain closed formulas when |G'|=p, and prove a closed all-r hierarchy in the Fq-Heisenberg family: \[ Pr(G)=q-2nrΣk=0(n,r)Ln,k(q)Πi=0k-1(qr-qi). \] In particular, inside the Fq-Heisenberg family the pair (P2(G),P3(G)) already determines the isoclinism class. Combining the cyclic-index formula with the known sharp upper bound for the multiple commutativity degree gives equality and near-extremal rigidity, including a stability gap near 11/32 for commuting triples. At the low-rank end we also prove explicit class-number formulas for P3(G) and P4(G); these recover the simple-count formulas for the untwisted Drinfeld double and the untwisted quantum triple / double-loop-groupoid algebra.