Primordial Black Hole Dark Matter in the Context of Extra Dimensions

TL;DR

This paper explores primordial black holes in theories with extra dimensions as a potential dark matter candidate, deriving their formation, evolution, and observational constraints across various scenarios.

Contribution

It provides a detailed derivation of the cosmological evolution and observational limits of extra-dimensional primordial black holes, highlighting their viability as dark matter.

Findings

LED PBHs can be a viable dark matter candidate for certain parameters.

Constraints on PBH masses range from 10 to 10^{21} grams.

For two extra dimensions, PBHs with mass around 10^{21} g remain unconstrained.

Abstract

Theories of large extra dimensions (LEDs) such as the Arkani-Hamed, Dimopoulos & Dvali scenario predict a "true" Planck scale $M_\star$ near the TeV scale, while the observed $M_{pl}$ is due to the geometric effect of compact extra dimensions. These theories allow for the creation of primordial black holes (PBHs) in the early Universe, from the collisional formation and subsequent accretion of black holes in the high-temperature plasma, leading to a novel cold dark matter (sub)component. Because of their existence in a higher-dimensional space, the usual relationship between mass, radius and temperature is modified, leading to distinct behaviour with respect to their 4-dimensional counterparts. Here, we derive the cosmological creation and evolution of such PBH candidates, including the greybody factors describing their evaporation, and obtain limits on LED PBHs from direct observation of evaporation products, effects on big bang nucleosynthesis, and the cosmic microwave background angular power spectrum. Our limits cover scenarios of 2 to 6 extra dimensions, and PBH masses ranging from 10 to $10^{21}$ g. We find that for two extra dimensions, LED PBHs represent a viable dark matter candidate with a range of possible black hole masses between $10^{17}$ and $10^{23}$ g depending on the Planck scale and reheating temperature. For $M_\star = 10$ TeV, this corresponds to PBH dark matter with a mass of $M \simeq 10^{21}$ g, unconstrained by current observations. We further refine and update constraints on "ordinary" four-dimension black holes.