The Q Branch Cooling Anomaly Can Be Explained by Mergers of White Dwarfs and Subgiant Stars

IF 8.8 1区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS Astrophysical Journal Letters Pub Date : 2023-09-28 DOI:10.3847/2041-8213/acf57b

Ken J. Shen, Simon Blouin, Katelyn Breivik

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Abstract

Abstract Gaia's exquisite parallax measurements allowed for the discovery and characterization of the Q branch in the Hertzsprung–Russell diagram, where massive C/O white dwarfs (WDs) pause their dimming due to energy released during crystallization. Interestingly, the fraction of old stars on the Q branch is significantly higher than in the population of WDs that will become Q branch stars or that were Q branch stars in the past. From this, Cheng et al. inferred that ∼6% of WDs passing through the Q branch experience a much longer cooling delay than that of standard crystallizing WDs. Previous attempts to explain this cooling anomaly have invoked mechanisms involving supersolar initial metallicities. In this paper, we describe a novel scenario in which a standard composition WD merges with a subgiant star. The evolution of the resulting merger remnant leads to the creation of a large amount of 26 Mg, which, along with the existing 22 Ne, undergoes a distillation process that can release enough energy to explain the Q branch cooling problem without the need for atypical initial abundances. The anomalously high number of old stars on the Q branch may thus be evidence that mass transfer from subgiants to WDs leads to unstable mergers.

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Q分支冷却异常可以用白矮星和次巨星的合并来解释

盖亚精细的视差测量允许在赫茨普龙-罗素图中发现和表征Q分支，其中大质量C/O白矮星(WDs)由于结晶过程中释放的能量而暂停变暗。有趣的是，Q分支上老恒星的比例明显高于将成为Q分支恒星或过去是Q分支恒星的WDs的比例。由此，Cheng等人推断，通过Q分支的约6%的WDs比标准结晶的WDs经历了更长的冷却延迟。先前解释这一冷却异常的尝试已经援引了与超级太阳初始金属丰度有关的机制。在这篇论文中，我们描述了一种新的情况，在这种情况下，标准成分WD与一颗亚巨星合并。由此产生的合并残余的演化导致了大量26mg的产生，它与现有的22ne一起经历了一个蒸馏过程，可以释放足够的能量来解释Q分支的冷却问题，而不需要非典型的初始丰度。因此，Q分支上异常多的老恒星可能证明了从亚巨星到WDs的质量转移导致了不稳定的合并。

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来源期刊

Astrophysical Journal Letters ASTRONOMY & ASTROPHYSICS-

CiteScore

14.10

自引率

6.30%

发文量

513

审稿时长

2-3 weeks

期刊介绍： The Astrophysical Journal Letters (ApJL) is widely regarded as the foremost journal for swiftly disseminating groundbreaking astronomical research. It focuses on concise reports that highlight pivotal advancements in the field of astrophysics. By prioritizing timeliness and the generation of immediate interest among researchers, ApJL showcases articles featuring novel discoveries and critical findings that have a profound effect on the scientific community. Moreover, ApJL ensures that published articles are comprehensive in their scope, presenting context that can be readily comprehensible to scientists who may not possess expertise in the specific disciplines covered.