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Hauptverfasser: Eriksson, Linn E. J., Xu, Ziyan, Lim, Jeonghoon, Yang, Chao-Chin, Huang, Pinghui, Mac Low, Mordecai-Mark
Format: Preprint
Veröffentlicht: 2026
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Online-Zugang:https://arxiv.org/abs/2603.17195
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author Eriksson, Linn E. J.
Xu, Ziyan
Lim, Jeonghoon
Yang, Chao-Chin
Huang, Pinghui
Mac Low, Mordecai-Mark
author_facet Eriksson, Linn E. J.
Xu, Ziyan
Lim, Jeonghoon
Yang, Chao-Chin
Huang, Pinghui
Mac Low, Mordecai-Mark
contents Clumping by streaming instability (SI) leading to gravitational collapse is the leading proposed mechanism for forming planetesimals, the building blocks of terrestrial planets and giant-planet cores. The critical dust-to-gas density ratio above which the SI leads to dust concentration strong enough to result in collapse depends on local dust properties and disk conditions, such as particle Stokes number, pressure gradient, and turbulence. The role of turbulence has recently drawn attention because simulations have shown that even modest levels of istropically forced turbulence can significantly increase the critical dust-to-gas ratio. However, we show that this does not hold for turbulence self-consistently generated by the magnetorotational instability (MRI). We present the first parameter study of the SI in three-dimensional, stratified, shearing-box simulations including non-ideal magnetohydrodynamics with ambipolar diffusion. Modest turbulence yields a clumping boundary similar to pure SI cases, while stronger turbulence does increase the critical dust-to-gas density ratio, though less than in the models where turbulence is isotropically forced. Particle concentration occurs inside zonal flows, large-scale structures generated by the MRI. Our results suggest that self-consistent, MRI-driven turbulence does not necessarily inhibit planetesimal formation.
format Preprint
id arxiv_https___arxiv_org_abs_2603_17195
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Planetesimal formation via the streaming instability persists under turbulence driven by magnetorotational instability
Eriksson, Linn E. J.
Xu, Ziyan
Lim, Jeonghoon
Yang, Chao-Chin
Huang, Pinghui
Mac Low, Mordecai-Mark
Earth and Planetary Astrophysics
Clumping by streaming instability (SI) leading to gravitational collapse is the leading proposed mechanism for forming planetesimals, the building blocks of terrestrial planets and giant-planet cores. The critical dust-to-gas density ratio above which the SI leads to dust concentration strong enough to result in collapse depends on local dust properties and disk conditions, such as particle Stokes number, pressure gradient, and turbulence. The role of turbulence has recently drawn attention because simulations have shown that even modest levels of istropically forced turbulence can significantly increase the critical dust-to-gas ratio. However, we show that this does not hold for turbulence self-consistently generated by the magnetorotational instability (MRI). We present the first parameter study of the SI in three-dimensional, stratified, shearing-box simulations including non-ideal magnetohydrodynamics with ambipolar diffusion. Modest turbulence yields a clumping boundary similar to pure SI cases, while stronger turbulence does increase the critical dust-to-gas density ratio, though less than in the models where turbulence is isotropically forced. Particle concentration occurs inside zonal flows, large-scale structures generated by the MRI. Our results suggest that self-consistent, MRI-driven turbulence does not necessarily inhibit planetesimal formation.
title Planetesimal formation via the streaming instability persists under turbulence driven by magnetorotational instability
topic Earth and Planetary Astrophysics
url https://arxiv.org/abs/2603.17195