A slightly oblate dark matter halo revealed by a retrograde precessing Galactic disk warp

IF 12.9 1区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS

Nature Astronomy Pub Date : 2024-06-27 DOI:10.1038/s41550-024-02309-5

Yang Huang, Qikang Feng, Tigran Khachaturyants, Huawei Zhang, Jifeng Liu, Juntai Shen, Timothy C. Beers, Youjun Lu, Song Wang, Haibo Yuan

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Abstract

The shape of the dark matter (DM) halo is key to understanding the hierarchical formation of the Galaxy. Despite extensive efforts in recent decades, however, its shape remains a matter of debate, with suggestions ranging from strongly oblate to prolate. Here, we present a new constraint on its present shape by directly measuring the evolution of the Galactic disk warp with time, as traced by accurate distance estimates and precise age determinations for about 2,600 classical Cepheids. We show that the Galactic warp is mildly precessing in a retrograde direction at a rate of ω = −2.1 ± 0.5 (statistical) ± 0.6 (systematic) km s−1 kpc−1 for the outer disk over the Galactocentric radius [7.5, 25] kpc, decreasing with radius. This constrains the shape of the DM halo to be slightly oblate with a flattening (minor axis to major axis ratio) in the range 0.84 ≤ qΦ ≤ 0.96. Given the young nature of the disk warp traced by Cepheids (less than 200 Myr), our approach directly measures the shape of the present-day DM halo. This measurement, combined with other measurements from older tracers, could provide vital constraints on the evolution of the DM halo and the assembly history of the Galaxy. Using a sample of more than 2,600 classical Cepheids with precise distances and ages, Huang et al. have discovered that the Milky Way’s disk warp undergoes retrograde precession, revealing the presence of a slightly oblate dark matter halo.

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逆行前冲银河盘翘曲揭示的略扁球形暗物质晕

暗物质（DM）光环的形状是理解银河系分层形成的关键。然而，尽管近几十年来我们做了大量工作，但它的形状仍是一个争论不休的问题，从强扁圆形到长圆形，各种说法不一而足。在这里，我们直接测量了银河盘翘曲随时间的演变，并通过对大约 2,600 个经典倒灶星的精确距离估计和精确年龄测定，对其目前的形状提出了新的约束。我们的研究表明，在银河系半径[7.5，25] kpc范围内，银河系外盘的翘曲以ω = -2.1 ± 0.5（统计）± 0.6（系统）km s-1 kpc-1的速率轻度逆行，并随着半径的减小而减小。这就约束了DM光环的形状，它略微扁平，扁平率（小轴与主轴之比）在0.84 ≤ qΦ ≤ 0.96的范围内。考虑到仙王座星系所追踪到的圆盘翘曲的年轻性质（小于200 Myr），我们的方法可以直接测量当今DM光环的形状。这一测量结果与其他更早的追踪器的测量结果相结合，可以为DM晕的演化和银河系的组装历史提供重要的约束条件。

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来源期刊

Nature Astronomy Physics and Astronomy-Astronomy and Astrophysics

CiteScore

19.50

自引率

2.80%

发文量

252

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