Abstract
In the companion paper [Phys. Rev. D 103, 104010 (2021)] we have derived the short-ranged potentials for the Teukolsky equations for massless spins (0, $1/2$, 1, 2) in general spherically symmetric and static metrics. Here we apply these results to numerically compute the Hawking radiation spectra of such particles emitted by black holes (BHs) in three different ansatz: charged BHs, higher-dimensional BHs, and polymerized BHs arising from models of quantum gravity. In order to ensure the robustness of our numerical procedure, we show that it agrees with newly derived analytic formulas for the cross sections in the high and low energy limits. We show how the short-ranged potentials and precise Hawking radiation rates can be used inside the code blackhawk to predict future primordial BH evaporation signals for a very wide class of BH solutions, including the promising regular BH solutions derived from loop quantum gravity. In particular, we derive the first Hawking radiation constraints on polymerized BHs from AMEGO. We prove that the mass window $1{0}^{16}--1{0}^{18}\text{ }\text{ }\mathrm{g}$ for all dark matter into primordial BHs can be reopened with high values of the polymerization parameter, which encodes the typical scale and strength of quantum gravity corrections.
Highlights
The most striking feature of black holes (BHs) might be that, in spite of their name, they radiate particles and slowly evaporate, as first discovered by Hawking [1]
We show how the short-ranged potentials and precise Hawking radiation rates can be used inside the code BlackHawk to predict future primordial BH evaporation signals for a very wide class of BH solutions, including the promising regular BH solutions derived from loop quantum gravity
We have extended the mass range to masses MPBH 1⁄4 1013 g, which is 2 orders of magnitude below the usual evaporation limit MPBH ≲ 1015 g set by the lifetime of the Primordial BHs (PBHs), because we expect that the decreased emission rates will result in an increased PBH lifetime, allowing smaller PBHs to contribute to dark matter (DM) today
Summary
The most striking feature of black holes (BHs) might be that, in spite of their name, they (supposedly) radiate particles and slowly evaporate, as first discovered by Hawking [1]. In a companion paper [8] we have derived the shortranged potentials of the Teukolsky equations for a wide class of BH solutions, namely spherically symmetric and static BHs, setting the mathematical background for HR computations. We compare our results at low and high energy with analytical limits, some of which are derived for the first time here This gives strong support for the robustness of our numerical method based on short-ranged potentials, which can be used to predict HR radiation signals for other BH metrics for which there is no analytical results yet.
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