The Black Hole History in Tamed Vacuum

Quantum physics at scales large compared to the Planck scale is described in the framework of classical space-time geometries. A criterion for selecting these backgrounds out of quantized gravity is proposed. It leads to an instability of the black-hole geometry, as experienced by motion across the horizon, against emission of Hawking quanta. A phenomenological treatment of the evaporation process perceived by external observers who do not cross the event horizon is presented. Evaporation occurs within a topologically trivial ``achronon" geometrical background devoid of horizons and singularities describing a collapse frozen up to decay time scales. It is ignited as in the conventional theory from pair creation out of the vacuum of the collapsing star of mass $M$, but after a time of order $M\ln M$ the source of thermal radiation shifts gradually to the star itself. This allows for a unitary evolution except possibly for exponentially small background transition amplitudes. The emerging picture is compared with approaches of t'Hooft and Susskind and the problem of its overall quantum consistency is evoked. (Figures available upon request)