Abstract
Low-mass planets migrate in the type-I regime. In the inviscid limit, the contrast between the vortensity trapped inside the planet's corotating region and the background disc vortensity leads to a dynamical corotation torque, which is thought to slow down inward migration. We investigate the effect of radiative cooling on low-mass planet migration using inviscid 2D hydrodynamical simulations. We find that cooling induces a baroclinic forcing on material U-turning near the planet, resulting in vortensity growth in the corotating region, which in turn weakens the dynamical corotation torque and leads to 2-3 × faster inw ard migration. This mechanism is most efficient when cooling acts on a time-scale similar to the U-turn time of material inside the corotating region, but is none the less rele v ant for a substantial radial range in a typical disc ( R ~5-50 au). As the planet migrates inwards, the contrast between the vortensity inside and outside the corotating region increases and partially regulates the effect of baroclinic forcing. As a secondary ef fect, we sho w that radiati ve damping can further weaken the vortensity barrier created by the planet's spiral shocks, supporting inward migration. Finally, we highlight that a self-consistent treatment of radiative diffusion as opposed to local cooling is critical in order to avoid overestimating the vortensity growth and the resulting migration rate.
| Original language | English |
|---|---|
| Pages (from-to) | 6130-6140 |
| Number of pages | 11 |
| Journal | Monthly Notices of the Royal Astronomical Society |
| Volume | 528 |
| Issue number | 4 |
| DOIs | |
| Publication status | Published - 2024 |
Funding
AZ would like to thank Roman Rafikov, Kees Dullemond, and Josh Brown for their suggestions and helpful discussions. This research utilized Queen Mary's Apocrita HPC facility, supported by QMUL Research-IT (http://doi.org/10.5281/zenodo.438045). This w ork w as performed using the DiRAC Data Intensive service at Leicester, operated by the University of Leicester IT Services, which forms part of the STFC DiRAC HPC Facility ( www.dirac.ac.uk). The equipment was funded by BEIS capital funding via STFC capital grants ST/K000373/1 and ST/R002363/1, and STFC DiRAC Operations grant ST/R001014/1. DiRAC is part of the National e-Infrastructure. AZ and RPN were supported by STFC grant ST/P000592/1, and RPN was supported by the Leverhulme Trust through grant RPG-2018- 418. This project has received funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (grant agreement no. 101054502). All plots in this paper were made with the PYTHON library MATPLOTLIB (Hunter 2007 ).Funding Information:
AZ would like to thank Roman Rafikov, Kees Dullemond, and Josh Brown for their suggestions and helpful discussions. This research utilized Queen Mary’s Apocrita HPC facility, supported by QMUL Research-IT ( http://doi.org/10.5281/zenodo.438045 ). This work was performed using the DiRAC Data Intensive service at Leicester, operated by the University of Leicester IT Services, which forms part of the STFC DiRAC HPC Facility ( www.dirac.ac.uk ). The equipment was funded by BEIS capital funding via STFC capital grants ST/K000373/1 and ST/R002363/1, and STFC DiRAC Operations grant ST/R001014/1. DiRAC is part of the National e-Infrastructure. AZ and RPN were supported by STFC grant ST/P000592/1, and RPN was supported by the Leverhulme Trust through grant RPG-2018-418. This project has received funding from the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (grant agreement no. 101054502). All plots in this paper were made with the python library matplotlib (Hunter ).
Keywords
- hydrodynamics
- methods: numerical
- planet-disc interactions