Reduction of dust radial drift by turbulence in protoplanetary disks

Fabiola Antonietta Gerosa, Jérémie Bec, Héloïse Méheut, Anand Utsav Kapoor
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Abstract

Dust particles in protoplanetary disks, lacking support from pressure, rotate at velocities exceeding those of the surrounding gas. Consequently, they experience a head-wind from the gas that drives them toward the central star. Radial drift occurs on timescales much shorter than those inferred from disk observations or those required for dust to aggregate and form planets. Additionally, turbulence is often assumed to amplify the radial drift of dust in planet-forming disks when modeled through an effective viscous transport. However, the local interactions between turbulent eddies and particles are known to be significantly more intricate than in a viscous fluid. Our objective is to elucidate and characterize the dynamic effects of Keplerian turbulence on the mean radial and azimuthal velocities of dust particles. We employ 2D shearing-box incompressible simulations of the gas, which is maintained in a developed turbulent state while rotating at a sub-Keplerian speed. Dust is modeled as Lagrangian particles set at a Keplerian velocity, therefore experiencing a radial force toward the star through drag. Turbulent eddies are found to reduce the radial drift, while simultaneously enhancing the azimuthal velocities of small particles. This dynamic behavior arises from the modification of dust trajectories due to turbulent eddies.
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原行星盘中的湍流减少了尘埃的径向漂移
原行星盘中的尘埃粒子由于缺乏压力的支持,其旋转速度超过了周围气体的旋转速度。径向漂移发生的时间尺度远远短于根据星盘观测推断的时间尺度,也远远短于尘埃聚集形成行星所需的时间尺度。我们的目标是阐明和描述开普勒湍流对尘埃粒子平均径向和方位速度的动态影响。我们对气体进行了二维剪切盒不可压缩模拟,气体保持在发达的湍流状态,同时以亚开普勒速度旋转。尘埃被模拟为以开普勒速度旋转的拉格朗日粒子,通过阻力向恒星施加径向力。湍流漩涡被发现可以减少径向漂移,同时增强小颗粒的方位角位移。这种动态行为源于湍流漩涡对尘埃轨迹的改良。
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