From formation to evaporation: Induced gravitational wave probes of the primordial black hole reheating scenario

arXiv - PHYS - High Energy Physics - Phenomenology Pub Date : 2024-09-18 DOI:arxiv-2409.12125

Guillem Domènech, Jan Tränkle

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Abstract

We study the Primordial Black Hole (PBH) reheating scenario, where PBHs originate in a general cosmological background. In this scenario, ultralight PBHs with masses $M\lesssim 10^8$g temporarily dominate the Universe and reheat it via Hawking radiation before Big Bang Nucleosynthesis (BBN). We investigate whether the induced Gravitational Wave (GW) spectrum associated with PBH reheating contains information about the pre-PBH-dominated stage, namely the initial equation of state $w$ (after inflation). We first derive the transfer functions of curvature fluctuations for general $w$ with adiabatic and isocurvature initial conditions. We find that, in general, a stiffer equation of state enhances the induced GW amplitude as it allows for a longer PBH dominated phase compared to the radiation dominated case. We also find that the spectral slope of GWs induced by primordial curvature fluctuations is sensitive to $w$, while the spectral slope of GWs induced by PBH number density fluctuations is not. Lastly, we derive constraints of the initial PBH abundance as a function of $w$, using BBN and Cosmic Microwave Background (CMB) observations. A stiffer equation of state leads to stricter constraints on the initial energy density fraction, as induced GWs are enhanced. Interestingly, we find that such induced GW signals may enter the observational window of several future GW detectors, such as LISA and the Einstein Telescope. Our formulas, especially the curvature fluctuation transfer functions, are applicable to any early matter-dominated universe scenario.

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从形成到蒸发：原始黑洞再加热情景的引力波探测器

我们研究了原始黑洞（PBH）再热情景，即原始黑洞起源于一般宇宙学背景。在这种情况下，质量为$M（小于10^8$g）的超轻黑洞暂时主宰宇宙，并在大爆炸核合成（BBN）之前通过霍金辐射重新加热宇宙。我们研究了与PBH再加热相关的诱导引力波（GW）谱是否包含PBH主导前阶段的信息，即初始状态方程$w$（暴胀之后）。我们首先推导了具有绝热和异曲率初始条件的一般 $w$ 的曲率波动传递函数。我们发现，一般来说，较硬的状态方程会增强诱导 GW 振幅，因为与辐射主导的情况相比，它允许较长的 PBH 主导阶段。我们还发现，原始曲率波动诱导的 GW 频谱斜率对 $w$ 敏感，而 PBH 数量密度波动诱导的 GW 频谱斜率则不敏感。最后，我们利用 BBN 和宇宙微波背景（CMB）观测数据，推导出了初始 PBH 丰度与 $w$ 函数关系的约束条件。较硬的状态方程会导致对初始能量密度分数的更严格约束，因为诱导全球变暖会增强。有趣的是，我们发现这种诱导全球变暖信号可能会进入未来几个全球变暖探测器的观测窗口，如 LISA 和爱因斯坦望远镜。我们的公式，尤其是曲率波动传递函数，适用于任何早期物质主导的宇宙场景。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - High Energy Physics - Phenomenology

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