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Radiating black holes in Einstein-Maxwell-dilaton theory and cosmic censorship violation

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arxiv 1512.08550 v3 pith:F7KMJBSO submitted 2015-12-28 hep-th gr-qc

Radiating black holes in Einstein-Maxwell-dilaton theory and cosmic censorship violation

classification hep-th gr-qc
keywords theorysolutionsblackchargedelectricallycasecensorshipcosmic
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We construct exact, time-dependent, black hole solutions of Einstein-Maxwell-dilaton theory with arbitrary dilaton coupling, $a$. For $a=1$ this theory arises as the four-dimensional low-energy effective description of heterotic string theory. These solutions represent electrically charged, spherically symmetric black holes emitting or absorbing charged null fluids and generalize the Vaidya and Bonnor-Vaidya solutions of general relativity and of Einstein-Maxwell theory, respectively. The $a=1$ case stands out as special, in the sense that it is the only choice of the coupling that allows for a time-dependent dilaton field in this class of solutions. As a by-product, when $a=1$ we show that an electrically charged black hole in this theory can be overcharged by bombarding it with a stream of electrically charged null fluid, resulting in the formation of a naked singularity. This provides an example of cosmic censorship violation in an exact dynamical solution to low-energy effective string theory and in a case in which the total stress-energy tensor satisfies all energy conditions. When $a\neq1$, our solutions necessarily have a time-independent scalar field and consequently cannot be overcharged.

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