English

Planet Migration in Windy Discs

Earth and Planetary Astrophysics 2024-11-08 v3 High Energy Astrophysical Phenomena Solar and Stellar Astrophysics

Abstract

Accretion of protoplanetary discs (PPDs) could be driven by MHD disc winds rather than turbulent viscosity. With a dynamical prescription for angular momentum transport induced by disc winds, we perform 2D simulations of PPDs to systematically investigate the rate and direction of planet migration in a windy disc. We find that the the strength of disc winds influences the corotation region similarly to the "desaturation" effect of viscosity. The magnitude and direction of torque depend sensitively on the hierarchy between the radial advection timescale across the horseshoe due to disc wind τdw\tau_{\rm dw}, the horsehoe libration timescale τlib\tau_{\rm lib} and U-turn timescale τUturn\tau_{\rm U-turn}. Initially, as wind strength increases and the advection timescale shortens, a non-linear horseshoe drag emerges when τdwτlib\tau_{\rm dw} \lesssim \tau_{\rm lib}, which tends to drive strong outward migration. Subsequently, the drag becomes linear and planets typically still migrate inward when τdwτUturnτlibh\tau_{\rm dw} \lesssim \tau_{\rm U-turn} \sim \tau_{\rm lib}h, where hh is the disc aspect ratio. For a planet with mass ratio of 105\sim 10^{-5}, the zone of outward migration sandwiched between inner and outer inward migration zones corresponds to \sim 10-100 au in a PPD with accretion rates between 10810^{-8} and 10710^{-7} Myr1M_\odot \text{yr}^{-1}.

Keywords

Cite

@article{arxiv.2410.19731,
  title  = {Planet Migration in Windy Discs},
  author = {Yinhao Wu and Yi-Xian Chen},
  journal= {arXiv preprint arXiv:2410.19731},
  year   = {2024}
}

Comments

6 pages, 5 figures, accepted by MNRAS Letters. Welcome any comments and suggestions!

R2 v1 2026-06-28T19:35:50.065Z