# Deforming black holes with odd multipolar differential rotation boundary

**Authors:** Shuo Sun, Tong-Tong Hu, Hong-Bo Li, Yong-Qiang Wang

arXiv: 1906.06183 · 2019-11-06

## TL;DR

This paper explores how odd multipolar differential rotation boundary conditions deform black holes and solitons in AdS$_4$, analyzing stability, horizon deformation, and quasinormal modes across temperature regimes.

## Contribution

It introduces new solutions with tripolar differential rotation boundary conditions and investigates their stability, horizon deformation, and quasinormal modes in the context of AdS$_4$ black holes.

## Key findings

- Maximal rotation parameters depend on temperature.
- High temperature solutions can be unstable due to superradiance.
- Horizon deformations are visualized via hyperbolic embedding.

## Abstract

Motivated by the novel asymptotically global AdS$_4$ solutions with deforming horizon in [JHEP {\bf 1802}, 060 (2018)], we analyze the boundary metric with odd multipolar differential rotation and numerically construct a family of deforming solutions with tripolar differential rotation boundary, including two classes of solutions: solitons and black holes. We find that the maximal values of the rotation parameter $\varepsilon$, below which the stable large black hole solutions could exist, are not a constant for $T> T_{schw}=\sqrt{3}/2\pi\simeq0.2757$. When temperature is much higher than $ T_{schw}$, even though the norm of Killing vector $\partial_{t}$ keeps timelike for some regions of $\varepsilon<2$, solitons and black holes with tripolar differential rotation could be unstable and develop hair due to superradiance. As the temperature $T$ drops toward $T_{schw}$, we find that though there exists the spacelike Killing vector $\partial_{t}$ for some regions of $\varepsilon>2$, solitons and black holes still exist and do not develop hair due to superradiance. Moreover, for $T\leqslant T_{schw}$, the curves of entropy firstly combine into one curve and then separate into two curves again, in the case of each curve there are two solutions at a fixed value of $\varepsilon$. In addition, we study the deformations of horizon for black holes by using an isometric embedding in the hyperbolic three-dimensional space. Furthermore, we also study the quasinormal modes of the solitons and black holes, which have analogous behaviours to that of dipolar rotation and quadrupolar rotation.

## Full text

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## Figures

26 figures with captions in the complete paper: https://tomesphere.com/paper/1906.06183/full.md

## References

34 references — full list in the complete paper: https://tomesphere.com/paper/1906.06183/full.md

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Source: https://tomesphere.com/paper/1906.06183