Nonextensive Behavior of Stellar Rotation in the Galactic Disk Components

IF 4.8 2区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS Astrophysical Journal Pub Date : 2023-11-01 DOI:10.3847/1538-4357/acfc3f

M. P. da Silva, M. M. F. de Lima, E. N. Velloso, J.-D. do Nascimento

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Abstract

Abstract The solar neighborhood is a unique stellar astrophysical laboratory formed by a variety of stars from different origins. In particular, two of the most notable populations known are the thick and thin disk stars, each characterized by distinct chemical compositions, ages, kinematics, and origins. Based on Tsallis nonextensive statistics, we investigate the observed distribution of the projected rotational velocity of the thin and thick disk component stars. Through Bayesian inference, our results show that the v sin i distributions of the Galactic disk populations selected from both kinematic and chemical criteria follow a nonextensive behavior, where non-Gaussian statistics provide a more accurate representation. We also observed an anticorrelation between the entropic index q and the age of disk components confirming the interpretation of initial angular momentum memory loss scaled by the parameter q . In contrast, a subextensivity case with q > 1 was found for the old high- α metal-rich subgroup h α mr, and due to their distinguished rotational behavior and atypical subextensive regime, we infer that thick disk and h α mr stars are, in fact, distinct objects. Our results also suggest that the rotational velocities of stars are defined not only by their evolutionary spin-down processes but also by their birth sites.

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星系盘成分中恒星旋转的非扩展行为

太阳邻域是由来自不同起源的各种恒星形成的独特的恒星天体物理实验室。特别值得一提的是，两种最著名的恒星群是厚盘星和薄盘星，每一种都有不同的化学成分、年龄、运动和起源。基于Tsallis的非广泛统计，我们研究了薄盘星和厚盘星的投影转速的观测分布。通过贝叶斯推断，我们的结果表明，从运动学和化学标准中选择的银河盘种群的v sin i分布遵循非扩展行为，其中非高斯统计提供了更准确的表示。我们还观察到熵指数q与磁盘组件年龄之间的反相关关系，证实了初始角动量记忆损失由参数q缩放的解释。与此相反，当q >1是在古老的高α富金属亚群h α mr中发现的，由于它们独特的旋转行为和非典型的亚扩张状态，我们推断厚盘星和h α mr星实际上是不同的物体。我们的结果还表明，恒星的旋转速度不仅取决于它们的演化自旋下降过程，还取决于它们的诞生地点。

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来源期刊

Astrophysical Journal 地学天文-天文与天体物理

CiteScore

8.40

自引率

30.60%

发文量

2854

审稿时长

1 months

期刊介绍： The Astrophysical Journal is the foremost research journal in the world devoted to recent developments, discoveries, and theories in astronomy and astrophysics.

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