Electromagnetic Counterparts Powered by Kicked Remnants of Black Hole Binary Mergers in AGN Disks

Chen, Ken; Dai, Zi-Gao

doi:10.3847/1538-4357/ad0dfd

Cited by 3 publications

(2 citation statements)

References 96 publications

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“…Numerous compact objects in the AGN disk inevitably form binary systems (Tagawa et al 2020;Rowan et al 2023;Wang et al 2024) via Jacobi capture (Wang et al 2021b), GW emission (Rom et al 2024), dynamical friction (Qian et al 2024), or the collision of their circumsingle disks (J. . Simulations of BBH evolution show that the complex interactions between the BBH and AGN disk induce the contraction of the BBH separation Li & Lai 2022;Dittmann et al 2024), leading to BBH mergers (Bartos et al 2017;Yang et al 2019;Yi & Cheng 2019;McKernan et al 2020;Samsing et al 2022), often followed by electromagnetic flares (Wang et al 2021b;Chen & Dai 2024;Tagawa et al 2023c), such as GRBs ( Perna et al 2021a;Lazzati et al 2022;Yuan et al 2022;Ray et al 2023) and GRB afterglow (Wang et al 2022). Additionally, WD collisions (Luo et al 2023;Zhang et al 2023) and kilonova emission from NS-NS/BH-NS mergers (Zhu et al 2021b;Ren et al 2022;Kathirgamaraju et al 2023) are also important probes for studying compact objects in AGN disks.…”

Section: Introductionmentioning

confidence: 99%

Accretion-modified Stars in Accretion Disks of Active Galactic Nuclei: Observational Characteristics in Different Regions of the Disks

Liu,

Wang,

Wang

2024

ApJ

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Stars and compact objects embedded in accretion disks of active galactic nuclei (AGNs), dubbed accretion-modified stars (AMSs), often experience hyper-Eddington accretion in the dense gas environment, resulting in powerful outflows as the Bondi explosion and formation of cavities. The varying gas properties across different regions of the AGN disk can give rise to diverse and intriguing phenomena. In this paper, we conduct a study on the characteristics of AMSs situated in the outer, middle, and inner regions of the AGN disk, where the growth of the AMSs during the shift inward is considered. We calculate their multiwavelength spectral energy distributions (SEDs) and thermal light curves. Our results reveal that the thermal luminosity of the Bondi explosion occurring in the middle region leads to UV flares with a luminosity of ∼1044 erg s−1. The synchrotron radiation of Bondi explosion in the middle and inner regions peaks at the X-ray band with luminosities of ∼1043 and ∼1042 erg s−1, respectively. The γ-ray luminosity of inverse Compton radiation spans from 1042–1043 erg s−1 peaked at the ∼10 MeV (outer region) and ∼GeV (middle and inner regions) bands. The observable flares of AMS in the middle region exhibit a slow rise and rapid Gaussian decay with a duration of months, while in the inner region, it exhibits a fast rise and slow Gaussian decay with a duration of several hours. These various SED and light-curve features provide valuable insights into the various astronomical transient timescales associated with AGNs.

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Section: Introductionmentioning

confidence: 99%

Accretion-modified Stars in Accretion Disks of Active Galactic Nuclei: Observational Characteristics in Different Regions of the Disks

Liu,

Wang,

Wang

2024

ApJ

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“…Especially, among these compact object mergers in AGN disks, BBH mergers have attracted the most attention since they have been prime targets for Earth-based gravitational wave (GW) detectors. Another important point is that BBH mergers embedded in AGN disks can potentially power their electromagnetic (EM) counterparts by accreting the abundant disk gas (Kimura et al 2021;Wang et al 2021;Tagawa et al 2022;Chen & Dai 2024), while in normal environment, accompanying EM radiation from BBH mergers is not expected because there is no accretion material to power a jet. Recently, seven AGN flares have been suggested to have a statistical association with LIGO/ Virgo BBH merging events (Graham et al 2023).…”

Section: Introductionmentioning

confidence: 99%

High-energy Neutrinos from Outflows Powered by the Kicked Remnants of Binary Black Hole Mergers in Active Galactic Nucleus Accretion Disks

Ma,

Wang

2024

ApJ

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Merging of stellar-mass binary black holes (BBHs) could take place within the accretion disks of active galactic nuclei (AGN). The resulting BH remnant is likely to accrete the disk gas at a super-Eddington rate, launching a fast, quasi-spherical outflow (wind). Particles will be accelerated by shocks driven by the wind, subsequently interacting with the shocked disk gas or radiation field through hadronic processes and resulting in the production of high-energy neutrinos and potential electromagnetic (EM) emission. This study delves into the intricate evolution of the shock driven by a merged BH wind within an AGN disk. Subsequently, we calculated the production of neutrinos and the expected detection numbers for a single event, along with their contributions to the overall diffuse neutrino background. Our analysis, which considers various scenarios, reveals considerable neutrino production and possible detection by IceCube for nearby events. The contribution of merged BH winds on the diffuse neutrino background is minor due to the low event rate density, but it can be improved to some extent for some optimistic parameters. We also propose that there could be two neutrino/EM bursts, one originating from the premerger BBH wind and the other from the merged BH wind, with the latter typically having a delay to the gravitational wave (GW) event of around tens of days. When combined with the anticipated GWs emitted during the BBH merger, such a system emerges as a promising candidate for joint observations involving neutrinos, GWs, and EM signals.

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Fast radio bursts in the discs of active galactic nuclei

Zhao,

Chen,

Wang

et al. 2024

Monthly Notices of the Royal Astronomical Society

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Fast radio bursts (FRBs) are luminous millisecond-duration radio pulses with extragalactic origin, which were discovered more than a decade ago. Despite the numerous samples, the physical origin of FRBs remains poorly understood. FRBs have been thought to originate from young magnetars or accreting compact objects (COs). Massive stars or COs are predicted to be embedded in the accretion disks of active galactic nuclei (AGNs). The dense disk absorbs FRBs severely, making them difficult to observe. However, progenitors’ ejecta or outflow feedback from the accreting COs interact with the disk material to form a cavity. The existence of the cavity can reduce the absorption by the dense disk materials, making FRBs escape. Here we investigate the production and propagation of FRBs in AGN disks and find that the AGN environments lead to the following unique observational properties, which can be verified in future observation. First, the dense material in the disk can cause large dispersion measure (DM) and rotation measure (RM). Second, the toroidal magnetic field in the AGN disk can cause Faraday conversion. Third, during the shock breakout, DM and RM show non-power-law evolution patterns over time. Fourth, for accreting-powered models, higher accretion rates lead to more bright bursts in AGN disks, accounting for up to 1 % of total bright repeating FRBs.

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Electromagnetic Counterparts Powered by Kicked Remnants of Black Hole Binary Mergers in AGN Disks

Cited by 3 publications

References 96 publications

Accretion-modified Stars in Accretion Disks of Active Galactic Nuclei: Observational Characteristics in Different Regions of the Disks

Accretion-modified Stars in Accretion Disks of Active Galactic Nuclei: Observational Characteristics in Different Regions of the Disks

High-energy Neutrinos from Outflows Powered by the Kicked Remnants of Binary Black Hole Mergers in Active Galactic Nucleus Accretion Disks

Fast radio bursts in the discs of active galactic nuclei

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