Large Order Enumerative Geometry, Black Holes and Black Rings

Abstract

Exploiting newly available data on Gopakumar-Vafa invariants at high genus for one-parameter hypergeometric Calabi-Yau threefolds, we study numerically the growth of the 5D indices, stable pair (PT) invariants and rank one Donaldson-Thomas (DT) invariants at large charges. For the 5D index Ω5D(d,m), below a critical value of the angular momentum m, we find perfect agreement with the Bekenstein-Hawking-Wald entropy of rotating 5D BMPV black holes, including the subleading correction from four-derivative interactions. When m exceeds the critical value, the 5D index is instead dominated by black rings with the smallest possible dipole charge. The stable pair invariant PT(d,m), which is determined by 5D indices, has a similar black ring/hole transition at negative m (now interpreted as the D0-brane charge) but surprisingly exhibits two other phase transitions at positive m: first, to a plateau and then to a polynomial growth m2d-1. In each phase, we derive an approximate expression for the invariant. Finally, the rank one DT invariant DT(d,m) is similar to PT(d,m) at negative m, and then transitions to a phase dominated by D0-branes, with entropy of order m2/3. Along the way, we determine the fixed genus, large degree behavior of GV invariants (including the overall g-dependent constant), extend it to an approximate formula valid also for large g, point out the unreasonable effectiveness of a simple PT/MSW relation, and study the growth of topological free energies at fixed degree, confirming a conjecture of Mariño.