湍流盘中的 I 型混沌迁移

Q1 Earth and Planetary Sciences
Yinhao Wu, Yi-Xian Chen, Douglas N C Lin
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引用次数: 0

摘要

通过利用驱动湍流模型对吸积盘进行全局流体力学模拟,我们证明了高水平的湍流会对嵌入这些盘中的低质量伴星产生高度随机的迁移力矩。这种情况适用于在原行星盘重力湍流区域内迁移的行星,以及嵌入活动星系核(AGN)吸积盘外围的恒星和黑洞。当湍流水平较低时,线性林德布拉德力矩会在随机力的背景下持续存在,其累积效应在相对较长的时间尺度内仍会占主导地位。然而,在湍流非常强烈的情况下,嵌入圆盘的伴星周围的经典流动模式会被打乱,导致在任意长的时间尺度上严重偏离经典的 I 型迁移理论的预期。我们的研究结果表明,湍流迁移的随机性会阻止低质量伴星在传统层状圆盘框架内单调地沉降到普遍迁移陷阱中,从而降低三体相互作用和分层合并的频率,而这是之前所预期的。我们提出了一个从经典迁移到混沌迁移的质量过渡比q∝αR,其中αR是雷诺粘滞应力参数。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Chaotic Type I Migration in Turbulent Discs
By performing global hydrodynamical simulations of accretion discs with driven turbulence models, we demonstrate that elevated levels of turbulence induce highly stochastic migration torques on low-mass companions embedded in these discs. This scenario applies to planets migrating within gravito-turbulent regions of protoplanetary discs as well as stars and black holes embedded in the outskirts of active galactic nuclei (AGN) accretion discs. When the turbulence level is low, linear Lindblad torques persists in the background of stochastic forces and its accumulative effect can still dominate over relatively long timescales. However, in the presence of very stronger turbulence, classical flow patterns around the companion embedded in the disc are disrupted, leading to significant deviations from the expectations of classical Type I migration theory over arbitrarily long timescales. Our findings suggest that the stochastic nature of turbulent migration can prevent low-mass companions from monotonically settling into universal migration traps within the traditional laminar disc framework, thus reducing the frequency of three-body interactions and hierarchical mergers compared to previously expected. We propose a scaling for the transition mass ratio from classical to chaotic migration q∝αR, where αR is the Reynolds viscosity stress parameter, which can be further tested and refined by conducting extensive simulations over the relevant parameter space.
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来源期刊
Monthly Notices of the Royal Astronomical Society: Letters
Monthly Notices of the Royal Astronomical Society: Letters Earth and Planetary Sciences-Space and Planetary Science
CiteScore
8.80
自引率
0.00%
发文量
136
期刊介绍: For papers that merit urgent publication, MNRAS Letters, the online section of Monthly Notices of the Royal Astronomical Society, publishes short, topical and significant research in all fields of astronomy. Letters should be self-contained and describe the results of an original study whose rapid publication might be expected to have a significant influence on the subsequent development of research in the associated subject area. The 5-page limit must be respected. Authors are required to state their reasons for seeking publication in the form of a Letter when submitting their manuscript.
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