Constraining PBH mass distributions from 21cm brightness temperature results and an analytical mapping between probability distribution of 21cm signal and PBH masses

Abstract The evaporation of primordial black hole (PBH) via Hawking radiation influences the evolution of Inter Galactic Medium by heating up the latter and consequently affects the 21cm signal originated from the neutral Hydrogen atoms. In this work, we have considered EDGES observational data of 2...

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Published inJournal of cosmology and astroparticle physics Vol. 2022; no. 10; pp. 99 - 121
Main Authors Mukhopadhyay, Upala, Majumdar, Debasish, Halder, Ashadul
Format Journal Article
LanguageEnglish
Published Bristol IOP Publishing 01.10.2022
Subjects
Black holes
Brightness temperature
dark energy theory
Dark matter
Error functions
Evaporation
Galactic evolution
Hawking radiation
Hydrogen atoms
physics of the early universe
primordial black holes
Probability distribution
Radiation
reionization
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Summary:Abstract The evaporation of primordial black hole (PBH) via Hawking radiation influences the evolution of Inter Galactic Medium by heating up the latter and consequently affects the 21cm signal originated from the neutral Hydrogen atoms. In this work, we have considered EDGES observational data of 21cm line corresponding to cosmic dawn era to constrain the mass and the abundance of PBHs. In this context, two different PBH mass distributions namely, power law and lognormal mass distributions are considered to estimate the effects of PBH evaporation on the 21cm brightness temperature T 21 . In addition to these two mass distributions, different monochromatic masses are also considered. The impacts of dark matter-baryon interactions on T 21 are also considered in this work along with the influences of PBH evaporation. Furthermore, adopting different monochromatic masses for PBHs, an attempt has been made to formulate a distribution for PBH masses by associating a probability weightage of the T 21 values (at z ∼ 17.2), within the range given by EDGES experiment, with the calculated T 21 values for each of the PBH mass values. The distribution best suited for the present purpose is found to be a combination of an error function and Owen function. Allowed contours in the parameter space of (initial PBH mass-dark matter mass) are obtained.
ISSN:1475-7516
1475-7516
DOI:10.1088/1475-7516/2022/10/099