Saving super-Earths: Interplay between pebble accretion and type I migration

Abstract: Overcoming type I migration and preventing low-mass planets from spiralling into the central star is a long-studied topic. It is well known that outward migration is possible in viscous-heated discs relatively close to the central star because the entropy gradient can be sufficiently steep that the positive corotation torque overcomes the negative Lindblad torque. Yet efficiently trapping planets in this region remains elusive. Here we study disc conditions that yield outward migration for low-mass planets under specific planet migration prescriptions. Using a steady-state disc model with a constant alpha-viscosity, outward migration is only possible when the negative temperature gradient exceeds ~0.87. We derive an implicit relation for the maximum mass at which outward migration is possible as a function of viscosity and disc scale height. We apply these criteria, using a simple power-law disc model, to planets that have reached their pebble isolation mass after an episode of rapid accretion. It is possible to trap planets with the pebble isolation mass farther than the inner edge of the disc provided that alpha_crit >~ 0.004 for discs older than 1 Myr. In very young discs the high temperature causes the planets to grow to masses exceeding the maximum for outward migration. As the disc evolves, these more massive planets often reach the central star, generally only towards the end of the disc's lifetime. Saving super-Earths is therefore a delicate interplay between disc viscosity, the opacity profile and the temperature gradient in the viscously heated inner disc.