Q. Pilate, A. López Ariste, A. Lavail, Ph. Mathias
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引用次数: 0
摘要
背景参宿四是一颗红超巨星(RSG),已知它在短时间和长时间尺度上都有半规则的变化。参宿四的短周期通常与径向脉动有关,但也可能是由于 RSG 表面的对流运动造成的。我们研究了表面活动与恒星变率之间的联系。参宿四的线性偏振是对流的一种代表,与脉动无关。我们利用贝特宙斯十年的光谱极化数据,在斯托克斯I、Q、U的最小二乘解卷积剖面图中寻找周期性,并利用伦布-斯卡格尔周期图寻找总线性极化。我们发现线性偏振信号中的周期与光度变异中的周期相似。400 d 的周期与我们数据的窗函数峰值过于接近,但 330 d 和 200 d 的两个周期出现在斯托克斯 Q 和 U 的周期图中,这表明参宿四的变化可以解释为由表面对流引起的。由于众所周知参宿四光谱中的线性偏振并不随脉动而变化,而是与表面对流有关,而且在光度测量和光谱偏振测量的时间序列中也发现了相似的周期,因此我们得出结论,光度测量的变化是由表面对流结构引起的,而不是由任何脉动现象引起的。
The variability of Betelgeuse explained by surface convection★
Context. Betelgeuse is a red supergiant (RSG) that is known to vary semi-regularly on both short and long timescales. The origin of the short period of Betelgeuse has often been associated with radial pulsations, but could also be due to the convection motions present at the surface of RSGs.Aims. We investigate the link between surface activity and the variability of the star.Methods. Linear polarization in Betelgeuse is a proxy of convection that is unrelated to pulsations. Using ten years of spectropolarimetric data of Betelgeuse, we looked for periodicities in the least-squares deconvolution profiles of Stokes I, Q, U and the total linear polarization using Lomb–Scargle periodograms.Results. We find periods in linear polarization signals that are similar to those in photometric variability. The 400 d period is too close to a peak of the window function of our data, but the two periods of 330 d and 200 d are present in the periodogram of Stokes Q and U, showing that the variability of Betelgeuse can be interpreted as being due to surface convection.Conclusions. Since the linear polarization in the spectrum of Betelgeuse is not known to vary with pulsations, but is linked to surface convection, and since similar periods are found in the time series of photometric measurements and spectropolarimetry, we conclude that the photometric variability is due to the surface convective structures, and not to any pulsation phenomenon.
期刊介绍:
Astronomy & Astrophysics is an international Journal that publishes papers on all aspects of astronomy and astrophysics (theoretical, observational, and instrumental) independently of the techniques used to obtain the results.