One month convection timescale on the surface of a giant evolved star

arXiv - PHYS - Solar and Stellar Astrophysics Pub Date : 2024-09-10 DOI:arxiv-2409.06785

W. Vlemmings, T. Khouri, B. Bojnordi Arbab, E. De Beck, M. Maercker

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Abstract

The transport of energy through convection is important during many stages of stellar evolution, and is best studied in our Sun or giant evolved stars. Features that are attributed to convection are found on the surface of massive red supergiant stars. Also for lower mass evolved stars, indications of convection are found, but convective timescales and sizes remain poorly constrained. Models indicate that convective motions are crucial for the production of strong winds that return the products of stellar nucleosynthesis into the interstellar medium. Here we report a series of reconstructed interferometric images of the surface of the evolved giant star R Doradus. The images reveal a stellar disc with prominent small scale features that provide the structure and motions of convection on the stellar surface. We find that the dominant structure size of the features on the stellar disc is $0.72\pm0.05$ astronomical units (au). We measure the velocity of the surface motions to vary between $-18$ and $+20$ km s$^{-1}$, which means the convective timescale is approximately one month. This indicates a possible difference between the convection properties of low-mass and high-mass evolved stars.

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一颗巨型演化恒星表面的一个月对流时间尺度

通过对流进行能量传输在恒星演化的许多阶段都很重要，对太阳或巨型演化恒星的研究最为深入。在质量较低的演化恒星中，也发现了对流的迹象，但对流的时间尺度和大小仍然没有得到很好的约束。模型表明，对流运动是产生强风的关键，强风将恒星核合成的产物送回星际介质。在这里，我们报告了一系列对演化巨星 R Doradus 表面的干涉测量重建图像。这些图像揭示了一个具有突出小尺度特征的恒星盘，这些特征提供了恒星表面对流的结构和运动。我们发现恒星盘上特征的主要结构尺寸为0.72/pm0.05$天文单位（au）。我们测得的表面运动速度在$-18$和$+20$ km s$^{-1}$之间变化，这意味着对流时间尺度大约为一个月。这表明低质量和高质量演化恒星的对流特性可能存在差异。

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arXiv - PHYS - Solar and Stellar Astrophysics

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