Black Hole Solutions in $R^2$ Gravity
Abstract
We find static spherically symmetric solutions of scale invariant gravity. The latter has been shown to be equivalent to General Relativity with a positive cosmological constant and a scalar mode. Therefore, one expects that solutions of the theory will be identical to that of Einstein theory. Indeed, we find that the solutions of gravity are in one-to-one correspondence with solutions of General Relativity in the case of non-vanishing Ricci scalar. However, scalar-flat solutions are global minima of the action and they cannot in general be mapped to solutions of the Einstein theory. As we will discuss, the solutions arise in Einstein gravity as solutions in the tensionless, strong coupling limit . As a further result, there is no corresponding Birkhoff theorem and the Schwarzschild black hole is by no means unique in this framework. In fact, gravity has a rich structure of vacuum static spherically symmetric solutions partially uncovered here. We also find charged static spherically symmetric backgrounds coupled to a field. Finally, we provide the entropy and energy formulas for the theory and we find that entropy and energy vanish for scalar-flat backgrounds.
Keywords
Cite
@article{arxiv.1502.04192,
title = {Black Hole Solutions in $R^2$ Gravity},
author = {Alex Kehagias and Costas Kounnas and Dieter Lust and Antonio Riotto},
journal= {arXiv preprint arXiv:1502.04192},
year = {2015}
}
Comments
19 pages, revised version with additional references