Critical dimensions and small cycle dominance from all-orders asymptotics of d-matrix theory
Abstract
Supersymmetric sectors of N=4 super-Yang-Mills theory motivate the study of the partition function for the counting of gauge-invariant functions of d=2,3 matrices transforming under the adjoint action of U(N). The partition function Zd ( x) in the large N limit has a known Hagedorn phase transition at x = d-1 which provides a simple model for the phase structure of the thermal partition function of SYM. We study the all-orders asymptotic expansion of Zd(x) based on a geometric picture of concentric circles of poles in the complex plane accumulating in a natural boundary at |x| =1. We find that the order by order structure has a precise combinatorial interpretation organized in terms of increasing cycle size of permutations arising in the enumeration of the invariants. We refer to this organization as small-cycle dominance, and find that it extends to refined versions of the partition functions depending on several complex variables. An analysis of the coefficients in the asymptotic expansion of Zd(x) using the modular property of the Dedekind eta function reveals that the asymptotic expansion is actually convergent for d d crit = 13. A fermionic version of Zd (x) has an analogous critical dimension of d crit = 7. This distinction indicates that the partition functions of the matrix models can be completely reconstructed from their high-energy (UV) limit for d d crit whereas additional input is required to reconstruct the exact coefficients of the low-energy (IR) expansion for 2 d d crit -1 .
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