Merger rate density of Population III binary black holes below, above, and in the pair-instability mass gap

Ataru Tanikawa, Hajime Susa, Takashi Yoshida, Alessandro A. Trani, Tomoya Kinugawa

Published 2020-08-05Version 1

We present the merger rate density of Population (Pop.) III binary black holes (BHs) by means of a widely-used binary population synthesis code {\tt BSE} with extensions to very massive and extreme metal-poor stars. We consider not only low-mass BHs (lBHs: $5-50M_\odot$) but also high-mass BHs (hBHs: $130-200M_\odot$), where lBHs and hBHs are below and above the pair-instability mass gap ($50-130 M_\odot$), respectively. Pop.~III BH-BHs can be categorized into three subpopulations: BH-BHs without hBHs (hBH0s: $m_{\rm tot} \lesssim 100M_\odot$), with one hBH (hBH1s: $m_{\rm tot} \sim 140-260M_\odot$), and with two hBHs (hBH2s: $m_{\rm tot} \sim 270-400M_\odot$), where $m_{\rm tot}$ is the total mass of a BH-BH. Their merger rate densities at the current universe are $\sim 0.1$ yr$^{-1}$ Gpc$^{-3}$ for hBH0s, and $\sim 0.01$ yr$^{-1}$ Gpc$^{-3}$ for the sum of hBH1s and hBH2s, using pessimistic Pop.~III star formation model. These rates are modestly insensitive to initial conditions and single star models. The hBH1 and hBH2 mergers can dominate BH-BHs with hBHs discovered in near future. They have low effective spins $\lesssim 0.2$ in the current universe. The number ratio of the hBH2s to the hBH1s is high, $\gtrsim 0.1$. We also find BHs in the mass gap (up to $\sim 85 M_\odot$) merge. These merger rates can be reduced to nearly zero if Pop.~III binaries are always wide ($\gtrsim 100R_\odot$), and if Pop.~III stars always enter into chemically homogeneous evolution. The presence of close Pop.~III binaries ($\sim 10R_\odot$) are crucial for avoiding the worst scenario.