Composite-Operator Scaling on Triadic Hypergraphs: Formation Transitions in Multi-Agent Architectures with Three-Body Coupling

Abstract

We study phase transitions on dynamic triadic hypergraphs, in which a continuous formation field evolves under stochastic Ginzburg--Landau dynamics with a cubic three-body coupling gτϕiϕjϕk, while a discrete opinion variable si∈\-1,+1\ undergoes Kawasaki exchange under a Hamiltonian with pairwise alignment and an irreducible three-body energy -λτΠa∈τsa. Near the formation critical point the cubic coupling is subleading and the transition remains continuous, controlled at leading order by a pairwise Ising baseline with renormalized coupling J eff=J+γw. The dominant observable is the triadic formation correlator Ψ formϕiϕjϕk, a k=3 composite operator built over the underlying Z2-symmetric order parameter. Composite-operator scaling yields the effective exponents β TF=3/2 and γ TF=-1. The susceptibility conjugate to Ψ form vanishes at the critical temperature Tc rather than diverging, in contrast to the divergence characterizing scalar (pairwise) order parameters. The exact partition function of the minimal triad on \-1,+1\3 identifies a crossover scale T*=4J eff/ 3. A field-theoretic two-point function argument reproduces the same vanishing susceptibility. Restoring the three-body coupling (λ≠0) makes the transition first-order, with a critical endpoint at λ=0. The exponent relations β TF=3β Ising and γ TF=γ Ising-4β Ising hold exactly on dense hypergraphs via cluster decomposition, and the vanishing-susceptibility signature persists for d≥3 but fails in d=2. A Mori--Zwanzig memory kernel yields a continuously tunable dynamical exponent z TF, completing the composite-operator scaling regime.