HD 110067 c has an aligned orbit. Measuring the Rossiter-McLaughlin effect inside a resonant multi-planet system with ESPRESSO

Astronomy & Astrophysics Pub Date : 2024-06-06 DOI:10.1051/0004-6361/202450570

J. Zak, H. Boffin, E. Sedaghati, A. Bocchieri, Q. Changeat, A. Fukui, A. Hatzes, T. Hillwig, K. Hornoch, D. Itrich, V. D. Ivanov, D. Jones, P. Kabáth, Y. Kawai, L. Mugnai, F. Murgas, N. Narita, E. Pallé, E. Pascale, P. Pravec, S. Redfield, G. Roccetti, M. Roth, J. Srba, Q. Tian, A. Tsiaras, D. Turrini, J. Vignes

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Abstract

Planetary systems in mean motion resonances hold a special place among the planetary population. They allow us to study planet formation in great detail as dissipative processes are thought to have played an important role in their existence. Additionally, planetary masses in bright resonant systems can be independently measured via both radial velocities and transit timing variations. In principle, they also allow us to quickly determine the inclination of all planets in the system since, for the system to be stable, they are likely all in coplanar orbits. To describe the full dynamical state of the system, we also need the stellar obliquity, which provides the orbital alignment of a planet with respect to the spin of its host star and can be measured thanks to the Rossiter-McLaughlin effect. It was recently discovered that HD 110067 harbors a system of six sub-Neptunes in resonant chain orbits. We here analyze an ESPRESSO high-resolution spectroscopic time series of HD 110067 during the transit of planet c. We find the orbit of HD 110067 c to be well aligned, with a sky-projected obliquity of $ $\,deg. This result indicates that the current architecture of the system was reached through convergent migration without any major disruptive events. Finally, we report transit-timing variation in this system as we find a significant offset of 19 pm 4 minutes in the center of the transit compared to the published ephemeris.

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HD 110067 c的轨道是对齐的。用 ESPRESSO 测量共振多行星系统内的罗西特-麦克劳林效应

平均运动共振中的行星系统在行星群中占有特殊的地位。由于耗散过程被认为在行星的形成过程中发挥了重要作用，因此我们可以通过它们来详细研究行星的形成过程。此外，明亮共振系统中的行星质量可以通过径向速度和凌日时间变化进行独立测量。原则上，它们还能让我们快速确定系统中所有行星的倾角，因为要使系统稳定，它们很可能都处于共面轨道上。为了描述该系统的全部动力学状态，我们还需要恒星斜度，它提供了行星相对于其主星自旋的轨道排列情况，并且可以通过罗西特-麦克劳林效应来测量。最近发现，HD 110067 中有一个由六颗处于共振链轨道上的亚海王星组成的系统。我们在这里分析了HD 110067在行星c凌日期间的ESPRESSO高分辨率光谱时间序列。我们发现HD 110067 c的轨道排列整齐，天空推算的斜度为$\,deg。这一结果表明，该系统目前的结构是在没有发生任何重大破坏事件的情况下通过会聚迁移形成的。最后，我们报告了这个系统的凌日时间变化，因为我们发现与公布的星历相比，凌日的中心偏移了19 pm 4分钟。

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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Astronomy & Astrophysics

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