Evidence of jet-caused 12-year optical periodicity of blazar OJ 287

IF 4.2 3区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS

Astroparticle Physics Pub Date : 2024-04-05 DOI:10.1016/j.astropartphys.2024.102965

Gorbachev M.A., Butuzova M.S., Nazarov S.V., Zhovtan A.V.

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Abstract

Blazar OJ 287 is one of the first candidates with the assumed compact system of two supermassive black holes in the center. Orbital interaction in this system has been used to explain the for over a century light curve, in which optical flares are repeated with a quasi-period of 12 years and have almost yearly duration. The absence of the predicted flare in 2022 casts doubt on the dominant model of a close system of binary black holes. The detection of optical flares outside the 12-year period and their interpretation by processes in the jet complicates the construction of a complete picture of the blazar OJ 287 optical variability. Here, we analyze the 50-year evolution of the optical spectrum and prove that the changing coefficient of relativistic boosting of two regions in a helical jet subject to an age-long orientation change forms all flares. Our findings indicate the absence of the compact binary black hole system and the impossibility of drawing reliable conclusions about the central engine of active galactic nuclei based only on the quasi-periodic brightness variability of blazars.

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OJ 287星12年光学周期性的喷流证据

Blazar OJ 287 是第一批候选者之一，其中心假定有两个超大质量黑洞组成的紧凑系统。该系统中的轨道相互作用被用来解释一个多世纪以来的光变曲线，其中光学耀斑以 12 年的准周期重复出现，持续时间几乎为一年。2022 年没有出现预言中的耀斑，这让人们对双黑洞近距离系统的主流模式产生了怀疑。在12年周期之外探测到的光学耀斑，以及喷流过程对它们的解释，使得构建OJ 287耀斑光学变异性的完整图景变得更加复杂。在这里，我们分析了光学光谱50年的演变过程，并证明了在一个螺旋喷流中，两个区域的相对论助推系数的变化形成了所有的耀斑，而这两个区域受到了长达一个时代的方位变化的影响。我们的研究结果表明不存在紧凑的双黑洞系统，也不可能仅仅根据类周期性的亮度变化就对活动星系核的中心引擎得出可靠的结论。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Astroparticle Physics 地学天文-天文与天体物理

CiteScore

8.00

自引率

2.90%

发文量

审稿时长

79 days

期刊介绍： Astroparticle Physics publishes experimental and theoretical research papers in the interacting fields of Cosmic Ray Physics, Astronomy and Astrophysics, Cosmology and Particle Physics focusing on new developments in the following areas: High-energy cosmic-ray physics and astrophysics; Particle cosmology; Particle astrophysics; Related astrophysics: supernova, AGN, cosmic abundances, dark matter etc.; Gravitational waves; High-energy, VHE and UHE gamma-ray astronomy; High- and low-energy neutrino astronomy; Instrumentation and detector developments related to the above-mentioned fields.