TriPoD:尘埃演化的三种群大小分布。原行星盘垂直整合流体力学模拟中的凝结现象

Thomas Pfeil, Til Birnstiel, Hubert Klahr
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摘要

背景。尘粒的凝结和破碎影响着原行星盘的结构和演变,并为行星的形成设定了初始条件。尘粒主宰着不透明性,决定着气体的冷却时间,影响着气体的电离状态,尘粒表面积是原行星盘化学反应的一个重要参数。因此,在原行星盘的数值研究中不应忽视尘埃的演化。然而,现有的尘埃凝聚模型计算成本太高,无法在大规模流体力学模拟中实施。这就限制了对原行星盘的详细数值研究,包括这些效应的研究,主要局限于一维模型。目的。我们的目标是建立一个简单但精确的尘埃凝结模型,以便在原行星盘的流体动力学模拟中实施。我们的模型不会明显增加模拟的计算成本,并能提供有关局部粒度分布的信息。方法。局部尘埃粒度分布被假定为截断幂律。这种分布可以用两种尘埃流体(大颗粒和小颗粒)和一个最大粒径来描述,截断幂律。我们将我们的模型与最先进的粉尘凝结模拟进行比较,并对其进行校准,使其与这些复杂的数值方法达到良好的拟合。结果。通过各种参数研究,我们的简化三参数模型与最先进的粉尘凝聚软件 DustPy 之间实现了良好的拟合。结论。我们介绍了 TriPoD,一种用于PLUTO 代码的子网格尘凝模型。利用 TriPoD,我们可以在流体力学模拟的基础上进行二维、垂直整合的尘埃凝聚模拟。因此,研究二维漩涡和行星盘系统中的尘埃分布成为可能。
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TriPoD: Tri-Population size distributions for Dust evolution. Coagulation in vertically integrated hydrodynamic simulations of protoplanetary disks
Context. Dust coagulation and fragmentation impact the structure and evolution of protoplanetary disks and set the initial conditions for planet formation. Dust grains dominate the opacities, they determine the cooling times of the gas, they influence the ionization state of the gas, and the grain surface area is an important parameter for the chemistry in protoplanetary disks. Therefore, dust evolution should not be ignored in numerical studies of protoplanetary disks. Available dust coagulation models are, however, too computationally expensive to be implemented in large-scale hydrodynamic simulations. This limits detailed numerical studies of protoplanetary disks, including these effects, mostly to one-dimensional models. Aims. We aim to develop a simple - yet accurate - dust coagulation model that can be implemented in hydrodynamic simulations of protoplanetary disks. Our model shall not significantly increase the computational cost of simulations and provide information about the local grain size distribution. Methods. The local dust size distributions are assumed to be truncated power laws. Such distributions can be characterized by two dust fluids (large and small grains) and a maximum particle size, truncating the power law. We compare our model to state-of-the-art dust coagulation simulations and calibrate it to achieve a good fit with these sophisticated numerical methods. Results. Running various parameter studies, we achieved a good fit between our simplified three-parameter model and DustPy, a state-of-the-art dust coagulation software. Conclusions. We present TriPoD, a sub-grid dust coagulation model for the PLUTO code. With TriPoD, we can perform two-dimensional, vertically integrated dust coagulation simulations on top of a hydrodynamic simulation. Studying the dust distributions in two-dimensional vortices and planet-disk systems is thus made possible.
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