上升,上升,远离:超热木星 WASP-76b 的风和动力学结构与高度的函数关系

Aurora Y. Kesseli, Hayley Beltz, Emily Rauscher, I. A. G. Snellen
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引用次数: 0

摘要

由于 10 米级望远镜上的新型高分辨率摄谱仪提供了前所未有的信号强度,以前所未有的精确度探索系外行星的三维性质成为可能。在本文中,我们提出了一种利用不同不透明度的行星吸收线集合来探测系外行星风的垂直结构和动力学的新技术,并将其应用于研究得很透彻的超热木星 WASP-76b。我们发现,已知的过境期间铁一吸收的不对称速度偏移在所有高度都持续存在,并观察到在大气层更深处有更强的蓝移和更窄的轮廓的初步趋势。通过比较三种不同的模型描述(无阻力流体力学模型、磁阻力模型和均匀阻力模型),我们能够排除均匀阻力模型,因为它与观测到的数据趋势不一致。我们发现磁力模型比流体动力模型略胜一筹,并注意到与低分辨率数据相比,这种 3 高斯运动学磁流体动力 GCM 也更胜一筹。未来的超大望远镜(ELTs)上的高分辨率摄谱仪将大大增加信号量,使类似的方法能够更精确地测量更多的天体。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Up, Up, and Away: Winds and Dynamical Structure as a Function of Altitude in the Ultra-Hot Jupiter WASP-76b
Due to the unprecedented signal strengths offered by the newest high-resolution spectrographs on 10-m class telescopes, exploring the 3D nature of exoplanets is possible with an unprecedented level of precision. In this paper, we present a new technique to probe the vertical structure of exoplanetary winds and dynamics using ensembles of planet absorption lines of varying opacity, and apply it to the well-studied ultra-hot Jupiter WASP-76b. We then compare these results to state-of-the-art global circulation models (GCMs) with varying magnetic drag prescriptions. We find that the known asymmetric velocity shift in Fe I absorption during transit persists at all altitudes, and observe tentative trends for stronger blueshifts and more narrow line profiles deeper in the atmosphere. By comparing three different model prescriptions (a hydrodynamical model with no drag, a magnetic drag model, and a uniform drag model) we are able to rule out the uniform drag model due to inconsistencies with observed trends in the data. We find that the magnetic model is slightly favored over the the hydrodynamic model, and note that this 3-Gauss kinematic magnetohydrodynamical GCM is also favored when compared to low-resolution data. Future generation high-resolution spectrographs on Extremely large telescopes (ELTs) will greatly increase signals and make methods like these possible with higher precision and for a wider range of objects.
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