负反馈和周围环境如何限制重组在共同包膜进化中的影响

IF 4.7 3区 物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS Monthly Notices of the Royal Astronomical Society Pub Date : 2024-01-09 DOI:10.1093/mnras/stae036
Luke Chamandy, Jonathan Carroll-Nellenback, Eric G Blackman, Adam Frank, Yisheng Tu, Baowei Liu, Yangyuxin Zou, Jason Nordhaus
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引用次数: 0

摘要

我们进行了三维流体力学模拟,以研究双星演化的共包层(CE)阶段的重组和电离,并开发了在时间和空间上跟踪离子转变的技术。我们模拟了一个 2 M⊙ 红巨分支主星和一个 1 M⊙ 伴星的相互作用,伴星被模拟为一个粒子。我们比较了采用表列状态方程(EOS)和理想气体状态方程(EOS)的运行情况,前者考虑了电离和重组。在模拟的前半部分,由于重组能量的释放,表列状态方程运行中未被束缚的质量比理想气体运行多出 15%,但到模拟结束时,两者之间的差异已经可以忽略不计。我们将此解释为以下原因造成的:(i) 表中的 EOS 运行经历了较浅的吸气,因此在后期释放的轨道能量较小,因为重组能量的释放使包层膨胀并减少了阻力;(ii) 膨胀的包层气体、抛射物和星周环境气体之间的碰撞和混合有助于解除包层的束缚,但在表中的 EOS 运行中,这种作用的效率较低,因为转移到束缚包层气体的部分能量被用于电离。在模拟的后半段,质量解除束缚的速率近似恒定,轨道分离度在后期稳步下降。根据简单的线性推断,CE阶段的持续时间为2年,之后包层将被解除束缚。
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How negative feedback and the ambient environment limit the influence of recombination in common envelope evolution
We perform 3D hydrodynamical simulations to study recombination and ionization during the common envelope (CE) phase of binary evolution, and develop techniques to track the ionic transitions in time and space. We simulate the interaction of a 2 M⊙ red giant branch primary and a 1 M⊙ companion modeled as a particle. We compare a run employing a tabulated equation of state (EOS) that accounts for ionization and recombination, with a run employing an ideal gas EOS. During the first half of the simulations, ∼15 per cent more mass is unbound in the tabulated EOS run due to the release of recombination energy, but by simulation end the difference has become negligible. We explain this as being a consequence of (i) the tabulated EOS run experiences a shallower inspiral and hence smaller orbital energy release at late times because recombination energy release expands the envelope and reduces drag, and (ii) collision and mixing between expanding envelope gas, ejecta and circumstellar ambient gas assists in unbinding the envelope, but does so less efficiently in the tabulated EOS run where some of the energy transferred to bound envelope gas is used for ionization. The rate of mass unbinding is approximately constant in the last half of the simulations and the orbital separation steadily decreases at late times. A simple linear extrapolation predicts a CE phase duration of ∼2yr, after which the envelope would be unbound.
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来源期刊
CiteScore
9.10
自引率
37.50%
发文量
3198
审稿时长
3 months
期刊介绍: Monthly Notices of the Royal Astronomical Society is one of the world''s leading primary research journals in astronomy and astrophysics, as well as one of the longest established. It publishes the results of original research in positional and dynamical astronomy, astrophysics, radio astronomy, cosmology, space research and the design of astronomical instruments.
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