The Eccentric and Accelerating Stellar Binary Black Hole Mergers in Galactic Nuclei: Observing in Ground and Space Gravitational Wave Observatories

Abstract

We study the stellar binary black holes (BBHs) inspiralling/merging in galactic nuclei based on our numerical method GNC. We find that 3-40\% of all new born BBHs will finally merge due to various dynamical effects. In a five year's mission, up to 104, 105, 100 of BBHs inspiralling/merging in galactic nuclei can be detected with SNR>8 in aLIGO, Einstein/DECIGO, TianQin/LISA/TaiJi, respectively. About tens are detectable in both LISA/TaiJi/TianQin and aLIGO. These BBHs have two unique characteristics: (1) Significant eccentricities. 1-3\%, 2-7\%, or 30-90\% of them is with ei>0.1 when they enter into aLIGO, Einstein, or space observatories, respectively. Such high eccentricities provide a possible explanation for that of GW 190521. Most highly-eccentric BBHs are not detectable in LISA/Tianqin/TaiJi before entering into aLIGO/Einstein as their strain become significant only at f GW0.1 Hz. DECIGO become an ideal observatory to detect those events as it can fully cover the rising phase. (2) Up to 2\% of BBHs can inspiral/merge at distances 103 r SW from the massive black hole (MBH), with significant accelerations, such that the Doppler phase drift of 10-105 of them can be detectable with SNR>8 in space observatories. The energy density of the gravitational wave backgrounds (GWB) contributed by these BBHs deviate from the powerlaw slope of 2/3 at f GW 1mHz. The high eccentricity, significant accelerations and different profile of GWB of these sources make them distinguishable, thus interesting for future GW detections and tests of relativities.