解开合并黑洞双星的起源

Proceedings of Gravitational-waves Science&Technology Symposium — PoS(GRASS2018) Pub Date : 2018-07-19 DOI:10.22323/1.325.0027

N. Giacobbo, M. Mapelli, M. Spera

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引用次数: 1

摘要

最近对引力波的探测已经证明了大质量恒星黑洞双星(BBHs)的存在，但BBHs的形成渠道仍然是一个悬而未决的问题。在这里，我们使用我们新的人口合成代码MOBSE来调查bbh的人口统计学。MOBSE是广泛使用的双星群合成代码BSE (Hurley et al. 2000, Hurley et al. 2002)的更新版本，包括决定大质量恒星命运的关键成分:最新的恒星风处方和超新星模型。通过MOBSE，我们可以在低金属丰度下形成总质量高达$\sim{}120$ M $_\odot$的bbh，但只有总质量高达$\sim{}80$ M $_\odot$的系统才会在不到哈勃时间内合并。我们的研究结果表明，只有大质量的贫金属恒星($Z\lesssim 0.002$)才能成为GW150914这样的引力波事件的起源。此外，我们预测，与富金属恒星相比，贫金属恒星形成合并黑洞的效率要高得多。

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Unravelling the progenitors of merging black hole binaries

The recent detection of gravitational waves has proven the existence of massive stellar black hole binaries (BBHs), but the formation channels of BBHs are still an open question. Here, we investigate the demography of BBHs by using our new population-synthesis code MOBSE. MOBSE is an updated version of the widely used binary population-synthesis code BSE (Hurley et al. 2000, Hurley et al. 2002) and includes the key ingredients to determine the fate of massive stars: up-to-date stellar wind prescriptions and supernova models. With MOBSE, we form BBHs with total mass up to $\sim{}120$ M$_\odot$ at low metallicity, but only systems with total mass up to $\sim{}80$ M$_\odot$ merge in less than a Hubble time. Our results show that only massive metal-poor stars ($Z\lesssim 0.002$) can be the progenitors of gravitational wave events like GW150914. Moreover, we predict that merging BBHs form much more efficiently from metal-poor than from metal-rich stars.

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Proceedings of Gravitational-waves Science&Technology Symposium — PoS(GRASS2018)

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