Black Holes: Scatterers, Absorbers and Emitters of Particles

TL;DR

This paper develops advanced analytic and computational methods to analyze black hole interactions with particles, revealing unique diffraction-like oscillatory absorption spectra and generalizing scattering theory to include black hole singularities.

Contribution

The paper introduces a novel approach to compute black hole absorption spectra, phase shifts, and Hawking emission rates, highlighting distinctive diffraction patterns caused by the black hole's singularity.

Findings

Black hole absorption spectrum exhibits oscillatory diffraction patterns.

Absorption occurs only at the singularity (r=0).

Features are expected to be universal across higher-dimensional black holes.

Abstract

Accurate and powerful analytic and computational methods developped by the author allow to obtain the highly non trivial total absorption spectrum of the Black Hole, as well as phase shifts and cross sections (elastic and inelastic), the angular distribution of absorbed and scattered waves, and the Hawking emission rates. The exact total absorption spectrum of waves by the Black Hole presents as a function of frequency a remarkable oscillatory behaviour characteristic of a diffraction pattern. It oscillates around its optical geometric limit (27/4) pi (r_s)^2 with decreasing amplitude and almost constant period. This is an unique distinctive feature of the black hole absorption, and due to its r=0 singularity. Ordinary absorptive bodies and optical models do not present these features. The Hamiltonian describing the wave-black hole interaction is non hermitian (despite being real) due to its singularity at the origin (r=0). The unitarity optical theorem of scattering theory is generalized to the black hole case explicitely showing that absorption takes place only at the origin (r = 0). All these results allow to understand and reproduce the Black Hole absorption spectrum in terms of Fresnel-Kirchoff diffraction theory. These fundamental features will be present for generic higher dimensional Black Hole backgrounds, and whatever the low energy effective theory they arise from. In recent and increasing litterature on absorption cross sections (`grey body factors') of black holes (whatever ordinary, stringy, D-braned), the fundamental remarkable features of the Black Hole Absorption spectrum are overlooked.