The joy of factorization at large $N$: five-dimensional indices and AdS black holes (2111.03069v1)
Abstract: We discuss the large $N$ factorization properties of five-dimensional supersymmetric partition functions for CFT with a holographic dual. We consider partition functions on manifolds of the form $\mathcal{M}= \mathcal{M}3 \times S2\epsilon$, where $\epsilon$ is an equivariant parameter for rotation. We show that, when $\mathcal{M}3$ is a squashed three-sphere, the large $N$ partition functions can be obtained by gluing elementary blocks associated with simple physical quantities. The same is true for various observables of the theories on $\mathcal{M}_3=\Sigma\mathfrak{g} \times S1$, where $\Sigma_\mathfrak{g}$ is a Riemann surface of genus $\mathfrak{g}$, and, with a natural assumption on the form of the saddle point, also for the partition function, corresponding to either the topologically twisted index or a mixed one. This generalizes results in three and four dimensions and correctly reproduces the entropy of known black objects in AdS$6 \times{w} S4$ and AdS$7\times S4$. We also provide the supersymmetric background and explicitly perform localization for the mixed index on $\Sigma\mathfrak{g} \times S1 \times S2_\epsilon$, filling a gap in the literature.