Dual CFT on Dyonic Kerr-Sen black hole and its gauged and ultraspinning counterparts

TL;DR

This paper establishes a holographic duality between rotating dyonic Kerr-Sen black holes in EMDA theory and 2D CFT, demonstrating entropy matching and exploring effects of charges, AdS length, and ultraspinning limits.

Contribution

It extends Kerr/CFT correspondence to dyonic Kerr-Sen-AdS black holes, including ultraspinning cases, with detailed analysis of central charges and entropy matching.

Findings

Exact entropy match between Bekenstein-Hawking and CFT calculations.

Duality holds for both Kerr-Sen-AdS and ultraspinning black holes.

Multiple branches of central charge depend on charge parameters and AdS length.

Abstract

We demonstrate that rotating dyonic black holes in Einstein-Maxwell-Dilaton-Axion (EMDA) theory is holographically dual with 2D conformal field theory. We first investigate the duality on dyonic Kerr-Sen black hole with non-vanishing dilaton and axion charges. The near-horizon geometry of extremal dyonic Kerr-Sen spacetime possesses the $SL(2,R) \times U (1)$ isometry allowing to employ the asymptotic symmetry group method to find the corresponding central charge. We find two different branches of the mass which correspond to CFT with two different central charges $c_L=12am_+$ and $c_L=12am_-$. The exact agreement between the Bekenstain-Hawking entropy and entropy from CFT is then found also in two different branches of extremal entropy. Furthermore, we demonstrate that this duality is robust insofar for non-zero AdS length. We show that the duality holds for both dyonic Kerr-Sen-AdS black hole and its ultraspinning counterpart. In both cases, we obtain the expected entropy from CFT which matches exactly with the Bekenstein-Hawking entropy. Since dyonic and axion charges are proportional to $1/m$, we note that there are possibly more than two branches of the central charge for non-zero AdS length in terms of mass. When we turn off dyonic charge, the axion charge vanishes showing the results of Kerr-Sen-AdS black hole. Moreover, when we assume the equal electromagnetic charges, it recovers the results when the dilaton charge vanishes. In the end, we compare the results of dyonic Kerr-Sen-AdS black hole and its ultraspinning counterpart to those of the dyonic Kerr-Newman-AdS black hole and the ultraspinning counterpart. Depending on the dyonic charge parameters, it is found that extremal ultraspinning dyonic Kerr-Sen-AdS black hole is not always superentropic.