受银河尺度星际湍流调控的行星形成

Andrew J. Winter, Myriam Benisty and Sean M. Andrews
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摘要

行星的形成是在由尘埃和气体组成的原行星盘内进行的,时间长达数百万年,人们通常认为原行星盘是孤立演化的。然而,在许多原行星盘周围发现了扩展的气态结构,这表明晚期来自星际介质(ISM)的内坠。为了量化晚期内陷的普遍程度,我们采用了一种偏移集形式主义来跟踪星盘寿命期间星际介质的局部密度和相对速度。然后,我们将理论上的邦迪-霍伊尔-莱特尔顿(BHL)吸积率与一个简单的磁盘演化模型结合起来,将恒星吸积的时间尺度与观测约束联系起来。磁盘寿命、质量、恒星吸积率和气态外半径与恒星质量和年龄的函数关系,都被我们这个只包括ISM吸积的简单模型很好地再现了。我们估计,20%-70%的磁盘可能主要由其生命周期最近一半的物质吸积组成,这表明磁盘特性并不能直接检验孤立演化模型。我们的计算表明,BHL吸积也能提供足够的能量来驱动粘性αSS∼10-5到10-1的原行星盘外部区域的湍流,尽管我们强调角动量传输,特别是吸积到恒星上的物质可能仍然是由内部过程驱动的。我们的简单方法可以很容易地应用于半解析模型。我们的研究结果令人信服地证明了行星的形成受到大尺度湍流的调控,并对行星形成理论产生了广泛的影响。这种可能性迫切需要进行深入观测,以证实或反驳我们的发现。
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Planet Formation Regulated by Galactic-scale Interstellar Turbulence
Planet formation occurs over a few Myr within protoplanetary disks of dust and gas, which are often assumed to evolve in isolation. However, extended gaseous structures have been uncovered around many protoplanetary disks, suggestive of late-stage infall from the interstellar medium (ISM). To quantify the prevalence of late-stage infall, we apply an excursion set formalism to track the local density and relative velocity of the ISM over the disk lifetime. We then combine the theoretical Bondi–Hoyle–Lyttleton (BHL) accretion rate with a simple disk evolution model, anchoring stellar accretion timescales to observational constraints. Disk lifetimes, masses, stellar accretion rates, and gaseous outer radii as a function of stellar mass and age are remarkably well reproduced by our simple model that includes only ISM accretion. We estimate that 20%−70% of disks may be mostly composed of material accreted in the most recent half of their lifetime, suggesting that disk properties are not a direct test of isolated evolution models. Our calculations indicate that BHL accretion can also supply sufficient energy to drive turbulence in the outer regions of protoplanetary disks with viscous αSS ∼ 10−5 to 10−1, although we emphasize that angular momentum transport and particularly accretion onto the star may still be driven by internal processes. Our simple approach can be easily applied to semianalytic models. Our results represent a compelling case for regulation of planet formation by large-scale turbulence, with broad consequences for planet formation theory. This possibility urgently motivates deep observational surveys to confirm or refute our findings.
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