Lauren Rhodes, Ben Margalit, Joe S. Bright, Hannah Dykaar, Rob Fender, David A. Green, Daryl Haggard, Assaf Horesh, Alexander J. van der Horst, Andrew K. Hughes, Kunal Mooley, Itai Sfaradi, David Titterington and David Williams-Baldwin
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引用次数: 0
Abstract
A tidal disruption event (TDE) occurs when a star travels too close to a supermassive black hole. In some cases, accretion of the disrupted material onto the black hole launches a relativistic jet. In this paper, we present a long-term observing campaign to study the radio and submillimeter emission associated with the fifth jetted/relativistic TDE: AT 2022cmc. Our campaign reveals a long-lived counterpart. We fit three different models to our data: a nonthermal jet, a spherical outflow consisting of both thermal and nonthermal electrons, and a jet with thermal and nonthermal electrons. We find that the data are best described by a relativistic spherical outflow propagating into an environment with a density profile following R−1.8. Comparison of AT 2022cmc to other TDEs finds agreement in the density profile of the environment but also that AT 2022cmc is twice as energetic as the other well-studied relativistic TDE, Swift J1644. Our observations of AT 2022cmc allow a thermal electron population to be inferred for the first time in a jetted transient, providing new insights into the microphysics of relativistic transients jets.
当恒星过于靠近超大质量黑洞时,就会发生潮汐破坏事件(TDE)。在某些情况下,被破坏的物质向黑洞的吸积会发射相对论性喷流。在本文中,我们提出了一个长期的观测活动来研究与第五喷射/相对论TDE: AT 2022cmc相关的射电和亚毫米发射。我们的竞选活动揭示了一个长期存在的对手。我们为我们的数据拟合了三种不同的模型:非热射流,由热电子和非热电子组成的球形流出,以及热电子和非热电子的射流。我们发现,这些数据最好的描述是一个相对论性的球形流出流传播到密度分布在R - 1.8以下的环境中。将at2022cmc与其他TDE进行比较,发现环境的密度分布是一致的,但也发现at2022cmc的能量是另一个经过充分研究的相对论TDE Swift J1644的两倍。我们对AT 2022cmc的观测首次推断出了射流瞬态中的热电子居群,为相对论性瞬态射流的微物理学提供了新的见解。
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