参宿四近伴星的径向速度和天体测量证据

Morgan MacLeod, Sarah Blunt, Robert J. De Rosa, Andrea K. Dupree, Thomas Granzer, Graham M. Harper, Caroline D. Huang, Emily M. Leiner, Abraham Loeb, Eric L. Nielsen, Klaus G. Strassmeier, Jason J. Wang, Michael Weber
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引用次数: 0

摘要

我们研究了一个世纪以来对距离我们最近的红超巨星参宿四的径向速度、目视星等和天体测量观测数据,以重新审视一个世纪以来关于参宿四可能是光谱双星的说法。这些数据显示,参宿四由于其沸腾的对流包层而在数年和数十年间随机变化,周期性地有一个 5.78 美元~年的长次级周期,而准周期性的脉动则有数百天的周期。我们的研究表明,天体测量数据集和 RV 数据集之间的长次级周期是一致的,并认为这表明参宿四有一颗小于一个太阳质量的低质量伴星,在 2110 天的周期内围绕参宿四运行,与参宿四的距离是参宿四半径的两倍多一点。这颗伴星的质量比参宿四小近 20 倍,比参宿四暗淡 100 万倍,有效温度与参宿四相似,因此可以有效地将它隐藏在夜空中研究最深入的恒星之一附近的平原视线中。天体测量数据显示这是一颗边缘双星,轨道平面与参宿四的测量旋轴对齐。潮汐自旋-轨道相互作用耗尽了轨道的角动量,使参宿四旋转起来,这就解释了自旋-轨道对齐和参宿四异常快速旋转的原因。在未来的一万年中,该轨道将逐渐衰减,直到伴星被参宿四吞噬。
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Radial Velocity and Astrometric Evidence for a Close Companion to Betelgeuse
We examine a century of radial velocity, visual magnitude, and astrometric observations of the nearest red supergiant, Betelgeuse, in order to reexamine the century-old assertion that Betelgeuse might be a spectroscopic binary. These data reveal Betelgeuse varying stochastically over years and decades due to its boiling, convective envelope, periodically with a $ 5.78$~yr long secondary period, and quasi-periodically from pulsations with periods of several hundred days. We show that the long secondary period is consistent between astrometric and RV datasets, and argue that it indicates a low-mass companion to Betelgeuse, less than a solar mass, orbiting in a 2,110 day period at a separation of just over twice Betelgeuse's radius. The companion star would be nearly twenty times less massive and a million times fainter than Betelgeuse, with similar effective temperature, effectively hiding it in plain sight near one of the best-studied stars in the night sky. The astrometric data favor an edge-on binary with orbital plane aligned with Betelgeuse's measured spin axis. Tidal spin-orbit interaction drains angular momentum from the orbit and spins up Betelgeuse, explaining the spin--orbit alignment and Betelgeuse's anomalously rapid spin. In the future, the orbit will decay until the companion is swallowed by Betelgeuse in the next 10,000 years.
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