Matrix models for 5d super Yang-Mills

Authors: Joseph A. Minahan Preprint Number: UUITP-17/16 In this contribution to the review on localization in gauge theories we investigate the matrix models derived from localizing N=1 super Yang-Mills on S^5.  We consider the large-N limit and attempt to solve the matrix model by a saddle-point approximation.  In general it is not possible to find an analytic solution, but at the weak and the strong limits of the 't Hooft coupling there are  dramatic simplifications that allows us to extract most of the interesting information.  At weak coupling we show that the matrix model is close to the Gaussian matrix model and that the free-energy scales as N^2.  At strong coupling we  show that if the theory contains one adjoint hypermultiplet then the free-energy scales as N^3.  We also find the expectation value of a supersymmetric Wilson loop that wraps the equator.  We demonstrate how to extract the effective couplings and reproduce results of Seiberg.  Finally, we compare to  results for the six-dimensional (2,0) theory  derived  using the AdS/CFT correspondence.  We show that by choosing the hypermultiplet mass such that the supersymmetry is enhanced to N=2,  the Wilson loop result matches the analogous calculation using AdS/CFT.  The free-energies differ by a rational fraction.