The Stochastic Gravitational Wave Background from Primordial Gravitational Atoms

Abstract

We propose a scenario of primordial gravitational atoms (PGAs), which may exist in the current and past universe due to spinning primordial black holes (PBHs) and very light bosonic fields. In a monochromatic mass scenario with a sizable dimensionless spin, which may arise in a short matter dominated (MD) era, we analyze the resulting stochastic gravitational wave background (SGWB) signal. Its spectrum is approximately characterized by a rising f3 followed by a falling f-1 where f is the frequency. Then, we investigate the constraints and prospects of such a SGWB, and find that PGAs with a core mass M BH O(10)~M and a cloud of light scalar with mass μ O (10-13) eV could yield constraints even stronger than those from bare PBHs. Future detectors such as LISA, Taiji and TianQin are able to explore PGAs over a narrow and elongated strap in the (μ,M BH) plane, spanning over 10 orders of magnitude for the maximum spin, 10-8~M M BH 104~M, 10-16~ eV μ 10-3~ eV. If the PGA is dressed with a vector cloud, the SGWB signal has a much better opportunity to be probed.

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