Horizon wave-function and the quantum cosmic censorship

We investigate the Cosmic Censorship Conjecture by means of the horizon wave-function (HWF) formalism. We consider a charged massive particle whose quantum mechanical state is represented by a spherically symmetric Gaussian wave-function, and restrict our attention to the superextremal case (with charge-to-mass ratio α>1α>1), which is the prototype of a naked singularity in the classical theory. We find that one can still obtain a normalisable HWF for α2<2α2<2, and this configuration has a non-vanishing probability of being a black hole, thus extending the classically allowed region for a charged black hole. However, the HWF is not normalisable for α2>2α2>2, and the uncertainty in the location of the horizon blows up at α2=2α2=2, signalling that such an object is no more well-defined. This perhaps implies that a quantum   Cosmic Censorship might be conjectured by stating that no black holes with charge-to-mass ratio greater than a critical value (of the order of 2) can exist.