三人探戈:人马座、LMC和银河系

E. Vasiliev, V. Belokurov, D. Erkal
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引用次数: 60

摘要

我们利用盖亚DR2的天文测量数据、天琴座RR恒星的距离估计以及各种光谱调查的视距速度,收集了具有5d和6d相空间信息的候选人马座流成员的目录。我们发现气流轨迹和气流前导臂反射修正的固有运动方向明显不一致,我们将其解释为引力势随时间扰动的特征。这种扰动的一个可能原因是最近银河系最大的卫星——大麦哲伦星云(LMC)的通过。我们开发了新的方法来模拟在LMC存在下的人马座流,使用专门定制的n体模拟和银河系晕密度曲线的灵活参数化。我们发现,虽然没有LMC的模型可以很好地拟合大多数流特征,但它们无法重现不对准,并且高估了到前导旋臂的距离。另一方面,LMC质量在(1-1.7)x10^11 m范围内的模型纠正了这些缺陷。我们证明,在一个静态的银河系中,流不能被充分地模拟。相反,我们的银河系需要向巨大的下落云倾斜,这给了人马座星云独特的形状和运动学。通过探索银河系势的参数空间,我们确定了100 kpc内的封闭质量为(5.2-6.0)x10^11 Msun,并初步发现了银晕形状和方向呈径向变化的证据。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Tango for three: Sagittarius, LMC, and the Milky Way
We assemble a catalogue of candidate Sagittarius stream members with 5d and 6d phase-space information, using astrometric data from Gaia DR2, distances estimated from RR Lyrae stars, and line-of-sight velocities from various spectroscopic surveys. We find a clear misalignment between the stream track and the direction of the reflex-corrected proper motions in the leading arm of the stream, which we interpret as a signature of a time-dependent perturbation of the gravitational potential. A likely cause of this perturbation is the recent passage of the most massive Milky Way satellite - the Large Magellanic Cloud (LMC). We develop novel methods for simulating the Sagittarius stream in the presence of the LMC, using specially tailored N-body simulations and a flexible parametrization of the Milky Way halo density profile. We find that while models without the LMC can fit most stream features rather well, they fail to reproduce the misalignment and overestimate the distance to the leading arm apocentre. On the other hand, models with an LMC mass in the range (1-1.7)x10^11 Msun rectify these deficiencies. We demonstrate that the stream can not be modelled adequately in a static Milky Way. Instead, our Galaxy is required to lurch toward the massive in-falling Cloud, giving the Sgr stream its peculiar shape and kinematics. By exploring the parameter space of Milky Way potentials, we determine the enclosed mass within 100 kpc to be (5.2-6.0)x10^11 Msun, and find tentative evidence for a radially-varying shape and orientation of the Galactic halo.
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