Modeling and searching for a stochastic gravitational-wave background from ultralight vector bosons

Leo Tsukada, R. Brito, W. East, Nils Siemonsen
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引用次数: 23

Abstract

Ultralight bosons, which are predicted in a variety of beyond-Standard-Model scenarios as dark-matter candidates, can trigger the superradiant instability around spinning black holes. This instability gives rise to oscillating boson condensates which then dissipate through the emission of nearly monochromatic gravitational waves. Such systems are promising sources for current and future gravitational-wave detectors. In this work, we consider minimally-coupled, massive vector bosons, which can produce a significantly stronger gravitational-wave signal compared to the scalar case. We adopt recently obtained numerical results for the gravitational-wave flux, and astrophysical models of black hole populations that include both isolated black holes and binary merger remnants, to compute and study in detail the stochastic gravitational-wave background emitted by these sources. Using a Bayesian framework, we search for such a background signal emitted using data from the first and second observing runs of Advanced LIGO. We find no evidence for such a signal. Therefore, the results allow us to constrain minimally coupled vector fields with masses in the range $0.8\times10^{-13}\mathrm{eV}\leq m_b\leq 6.0\times10^{-13}\mathrm{eV}$ at 95% credibility, assuming optimistically that the dimensionless spin distribution for the isolated black hole population is uniform in the range $[0,1]$. With more pessimistic assumptions, a narrower range around $m_b\approx 10^{-13}\mathrm{eV}$ can still be excluded as long as the upper end of the uniform distribution for dimensionless black hole spin is $\gtrsim 0.2$.
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超轻矢量玻色子的随机引力波背景建模与搜索
超轻玻色子被预测为各种超越标准模型的暗物质候选者,它可以引发旋转黑洞周围的超辐射不稳定性。这种不稳定性产生了振荡玻色子凝聚体,然后通过发射几乎单色的引力波而消散。这样的系统是当前和未来引力波探测器很有希望的来源。在这项工作中,我们考虑了最小耦合的大质量矢量玻色子,与标量情况相比,它可以产生更强的引力波信号。我们采用最近获得的引力波通量的数值结果,以及包括孤立黑洞和二元合并残余物在内的黑洞群体的天体物理模型,对这些源发射的随机引力波背景进行了详细的计算和研究。使用贝叶斯框架,我们使用高级LIGO第一次和第二次观测运行的数据来搜索这样的背景信号。我们没有发现这种信号存在的证据。因此,结果允许我们约束质量在$0.8\times10^{-13}\mathrm{eV}\leq m_b\leq 6.0\times10^{-13}\mathrm{eV}$范围内的最小耦合向量场% credibility, assuming optimistically that the dimensionless spin distribution for the isolated black hole population is uniform in the range $[0,1]$. With more pessimistic assumptions, a narrower range around $m_b\approx 10^{-13}\mathrm{eV}$ can still be excluded as long as the upper end of the uniform distribution for dimensionless black hole spin is $\gtrsim 0.2$.
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