Exact Solvability via the KP Hierarchy for β=L2 Random Matrix Ensembles

Abstract

Random matrix ensembles with Dyson index β=L2 describe systems of M charge-L particles interacting logarithmically in the presence of an external potential, yet exact formulas for their physical observables have remained elusive for L≠ 1,2. We show that, for L even, β=L2 ensembles are governed by the KP hierarchy at finite particle number--paralleling the KP solvability of classical β=1,2,4 ensembles. The partition function is a hyperpfaffian τ-function satisfying the Hirota bilinear identity, and correlation functions are generated by finite-order differential operators acting on this τ-function. The key mechanism is an emergent quantized momentum that stratifies the system into discrete sectors, enforcing momentum conservation as a selection rule. This produces a dramatic dimensional reduction from LM L to O(L2M), enabling explicit computation of physical observables.