TURKISH JOURNAL OF PHYSICS, sa.3, 2024 (ESCI)
We investigate the effects of an early cosmological period dominated by primordial 2 -2 -holes on axion dark matter. The 2 -2 -holes emerge as a new family of horizonless classical solutions for ultracompact matter distributions in quadratic gravity, a candidate theory of quantum gravity. Thermal 2 -2 -holes, sourced by relativistic thermal gas, exhibit Hawking -like radiation and fulfill the entropy -area law before they become remnants with almost no radiation. In this paper, we consider the remnant contribution to dark matter (DM) small and adopt the axion DM scenario by the misalignment mechanism. We show that a 2 -2 -hole domination phase in the evolution of the universe changes the axion mass window, obtained from the dark matter abundance constraints. The biggest effect occurs when the remnants have the Planck mass, which is the case for a strongly coupled quantum gravity. The change in abundance constraints for the Planck mass 2 -2 -hole remnants amounts to that of the primordial black hole (PBH) counterpart. Therefore, since we use the revised constraints from gravitational waves on the initial fraction of 2 -2 -holes, the results here can also be considered the updated version of the PBH case. As a result, the lower limit on the axion mass is found as m a similar to 10 - 9 eV. Furthermore, the domination scenario itself constrains the remnant mass M min considerably. Given that we focus on the pre-BBN domination scenario in order not to interfere with BBN (Big Bang nucleosynthesis) constraints, the remnant mass window becomes m Pl <= M min <= 0.1 g .