Astrophysical Gravitational-Wave Echoes from Galactic Nuclei
Abstract
Galactic nuclei (GNs) are dense stellar environments abundant in gravitational-wave (GW) sources for LIGO, VIRGO, and KAGRA. The GWs may be generated by stellar-mass black hole (BH) or neutron star mergers following gravitational bremsstrahlung, dynamical scattering encounters, Kozai-Lidov type oscillations driven by the central supermassive black hole (SMBH), or gas-assisted mergers if present. In this paper, we examine a smoking gun signature to identify sources in GNs: the GWs scattered by the central SMBH. This produces a secondary signal, an astrophysical GW echo, which has a very similar time-frequency evolution as the primary signal but arrives after a time delay. We determine the amplitude and time-delay distribution of the GW echo as a function of source distance from the SMBH. Between 10\%-90\% of the detectable echoes arrive within (1-100)M6\,sec after the primary GW for sources between 10-104 Schwarzschild radius, where M6=M SMBH,z/(106\,M), and M SMBH,z is the observer-frame SMBH mass. The echo arrival times are systematically longer for high signal-to-noise ratio (SNR) primary GWs, where the GW echo rays are scattered at large deflection angles. In particular, 10\%-90\% of the distribution is shifted to (5-1800)M6\,sec for sources, where the lower limit of echo detection is 0.02 of the primary signal amplitude. We find that 5\%-30\% (1\%-7\%) of GW sources have an echo amplitude larger than 0.2-0.05 times the amplitude of the primary signal if the source distance from the SMBH is 50 (200) Schwarzschild radius. Non-detections can rule out that a GW source is near an SMBH.
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