Constraints on the Primordial Black Hole Abundance through Scalar-Induced Gravitational Waves from Advanced LIGO and Virgo's First Three Observing Runs

arXiv - PHYS - High Energy Physics - Theory Pub Date : 2024-09-12 DOI:arxiv-2409.07976

Yang Jiang, Chen Yuan, Chong-Zhi Li, Qing-Guo Huang

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Abstract

As a promising dark matter candidate, primordial black holes (PBHs) lighter than $\sim10^{-18}M_{\odot}$ are supposed to have evaporated by today through Hawking radiation. This scenario is challenged by the memory burden effect, which suggests that the evaporation of black holes may slow down significantly after they have emitted about half of their initial mass. We explore the astrophysical implications of the memory burden effect on the PBH abundance by today and the possibility for PBHs lighter than $\sim10^{-18}M_{\odot}$ to persist as dark matter. Our analysis utilizes current LIGO-Virgo-KAGRA data to constrain the primordial power spectrum and infers the PBH abundance. We find a null detection of scalar-induced gravitational waves that accompanied the formation of the PBHs. Then we place an upper limit on the primordial power spectrum and the PBH abundance to be $f_{\mathrm{pbh}}\simeq0.3$ for PBHs with masses $\sim10^{-24}M_{\odot}$. Furthermore, we expect that next-generation gravitational wave detectors, such as the Einstein Telescope and the Cosmic Explorer, will provide even more stringent constraints. Our results indicate that future detectors can reach sensitivities that could rule out PBH as dark matter within $\sim[10^{-29}M_{\odot},10^{-19}M_{\odot}]$ in the null detection of scalar-induced gravitational waves.

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通过高级 LIGO 和处女座前三次观测运行产生的标量诱发引力波对原始黑洞丰度的约束

作为一种有希望的暗物质候选者，重量小于$\sim10^{-18}M_{\odot}$的原始黑洞（PBHs）被认为在今天已经通过霍金辐射蒸发了。这种假设受到了记忆负担效应的挑战，记忆负担效应表明，黑洞的蒸发速度可能会在它们释放了大约一半的初始质量之后显著减慢。我们探讨了记忆负担效应对当今PBH丰度的物理影响，以及轻于$\sim10^{}-18M_{\odot}$的PBH作为暗物质存在的可能性。我们的分析利用当前的LIGO-Virgo-KAGRA数据来约束原始功率谱，并推断PBH丰度。我们完全探测到了伴随 PBH 形成的标量诱导引力波。然后，对于质量为$\sim10^{-24}M_{\odot}$的PBHs，我们将原始功率谱和PBH丰度的上限设定为$f_{mathrm{pbh}}\simeq0.3$。此外，我们预计爱因斯坦望远镜和宇宙探索者等下一代引力波探测器将提供更加严格的约束。我们的结果表明，在标量诱导引力波的空探测中，未来探测器的灵敏度可以达到$\sim[10^{-29}M_{\odot},10^{-19}M_\odot}]$以内，从而排除PBH作为暗物质的可能性。

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arXiv - PHYS - High Energy Physics - Theory

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