Constraints on Primordial Black Holes from Galactic Diffuse Synchrotron Emissions

Abstract

We investigate the possibility of constraining primordial black holes (PBHs) with masses MPBH 1015\,g through Galactic diffuse synchrotron emissions. Due to Hawking radiation, these types of PBHs are expected to be stable sources of cosmic-ray (CR) electrons and positrons with energies below O(10\,MeV). In many CR propagation models with diffusive re-acceleration characterized by a significant Alfv\'en velocity Va O(10)\,km/s, the energies of the evaporated electrons/positrons can be further enhanced to O(100)\,MeV through their scattering with the Galactic random magnetic fields. Consequently, the observation of Galactic synchrotron emissions at frequencies above 20\,MHz can provide useful constraints on the abundance of PBHs. Using the AMS-02 and Voyager-1 data on the boron-to-carbon nuclei flux ratio, we confirm that a significant Alfv\'en velocity Va 20\,km/s is favored in several benchmark diffusive re-acceleration models. We show that, in this scenario, the observed low-frequency synchrotron emissions (from 22 MHz to 1.4 GHz) can provide stringent constraints on PBH abundance. The obtained conservative constraints are stronger than those derived from the Voyager-1 all-electron (electron plus positron) data by more than one order of magnitude for MPBH 1× 1016\,g, and also stronger than our previous constraints derived from the AMS-02 positron data for MPBH 2× 1016\,g.