Game Conductors of Finite Groups: Determinantal Torsion from Structured Payoff Probes

Abstract

We attach to a finite group G and a structured payoff probe ϕ an integer payoff-difference lattice Mϕ(G) and its conductor Cϕ(G): the primes at which Mϕ(G) loses rank modulo p. Our main result is an exact computation: for any CA-group the commuting conductor is rad(b-1), where b is the number of maximal abelian subgroups. In particular, conductor primes need not divide |G|: the prime 3 occurs for a 2-group of order 64 with b=7. The commuting Smith spectrum is an invariant of the isoclinism class and obeys an exact direct-product law, giving Ccomm(G× H) = Ccomm(G) Ccomm(H) unconditionally. A Galois-orbit-trace character probe reads a complementary layer: an index-2 subgroup forces 2∈ Cchar(G) while no odd prime is forced, and Ccomm(D2q) = \q\, Cchar(D2q) = \2\ for all odd primes q. Certified exhaustive computation (|G|128 commuting, |G|64 character) and a deformation-family analysis support the general program: classify the Smith torsion of the compressed centralizer-type incidence matrix BG.

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