Radiation enhancement and "temperature" in the collapse regime of gravitational scattering

Abstract

We generalize the semiclassical treatment of graviton radiation to gravitational scattering at very large energies s mP and finite scattering angles s, so as to approach the collapse regime of impact parameters b bc R 2Gs. Our basic tool is the extension of the recently proposed, unified form of radiation to the ACV reduced-action model and to its resummed-eikonal exchange. By superimposing that radiation all-over eikonal scattering, we are able to derive the corresponding (unitary) coherent-state operator. The resulting graviton spectrum, tuned on the gravitational radius R, fully agrees with previous calculations for small angles s 1 but, for sizeable angles s(b)≤ c = O(1) acquires an exponential cutoff of the large ω R region, due to energy conservation, so as to emit a finite fraction of the total energy. In the approach-to-collapse regime of b bc+ we find a radiation enhancement due to large tidal forces, so that the whole energy is radiated off, with a large multiplicity N Gs 1 and a well-defined frequency cutoff of order R-1. The latter corresponds to the Hawking temperature for a black hole of mass notably smaller than s.