Harnessing S-Duality in N=4 SYM & Supergravity as SL(2,Z)-Averaged Strings

Abstract

We develop a new approach to extracting the physical consequences of S-duality of four-dimensional N=4 super Yang-Mills (SYM) and its string theory dual, based on SL(2,Z) spectral theory. We observe that CFT observables O, invariant under SL(2,Z) transformations of a complexified gauge coupling τ, admit a unique spectral decomposition into a basis of square-integrable functions. This formulation has direct implications for the analytic structure of N=4 SYM data, both perturbatively and non-perturbatively in all parameters. For example, k-instanton sectors are uniquely determined by the zero- and one-instanton sectors, and Borel summable series around k-instantons have convergence radii with simple k-dependence. In large N limits, we derive the existence and scaling of non-perturbative effects, which we exhibit for certain N=4 SYM observables. An elegant benchmark for these techniques is the integrated four-point function conjecturally determined by [arXiv:2102.09537] for all τ for SU(N) gauge group; we derive and elucidate its form. These results have ramifications for holography. We explain how , the ensemble average over the N=4 supersymmetric conformal manifold with respect to the Zamolodchikov measure, is cleanly isolated by the spectral decomposition. We prove that the large N limit of equals the large N, large 't Hooft coupling limit of O. Holographically speaking, = O sugra, its value in type IIB supergravity on AdS5 × S5. This result, which extends to all orders in 1/N, embeds ensemble averaging into the traditional AdS/CFT paradigm. The statistics of the SL(2,Z) ensemble exhibit both perturbative and non-perturbative 1/N effects.