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Black holes in higher-derivative gravity theories

S. MignemiDepartment of Physics, University of Newcastle-Upon-Tyne, Newcastle-Upon-Tyne NE1 7RU, United KingdomDavid L. WiltshireDepartment of Physics and Mathematical Physics, University of Adelaide, GPO Box 498, Adelaide, South Australia 5001, Australia
1992en
ABI

Аннотация

We study static spherically symmetric solutions of Einstein gravity plus an action polynomial in the Ricci scalar $R$ of arbitrary degree $n$ in an arbitrary dimension $D$. The global properties of all such solutions are derived by studying the phase space of field equations in the equivalent theory of gravity coupled to a scalar field, which is obtained by a field redefinition and conformal transformation. The following uniqueness theorem is obtained: Provided that the coefficient ${a}_{2}$ of the ${R}^{2}$ term in the Lagrangian polynomial is positive then the only static spherically symmetric asymptotically flat solution with a regular horizon in these models is the Schwarzschild solution. Other branches of solutions with regular horizons, which are asymptotically anti-de Sitter, or de Sitter, are also found. An exact Schwarzschild-de Sitter-type solution is found to exist in the $R+a{R}^{2}$ theory if $D>4$. If terms of cubic or higher order in $R$ are included in the action, then such solutions also exist in four dimensions. The general Schwarzschild-de Sitter-type solution for arbitrary $D$ and $n$ is given. The fact that the Schwarzschild solution in these models does not coincide with the exterior solution of physical bodies such as stars has important physical implications which we discuss. As a byproduct, we classify all static spherically symmetric solutions of $D$-dimensional gravity coupled to a scalar field with a potential consisting of a finite sum of exponential terms.

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