Radiative feedback from protoplanets in self-gravitating protoplanetary discs

TL;DR

This paper investigates how radiative feedback from forming protoplanets influences their growth and migration in self-gravitating protoplanetary discs, revealing that it can prevent gas accretion and favor planet formation.

Contribution

It introduces the role of radiative feedback in protoplanet evolution, showing its impact on migration and mass accumulation, which was overlooked in previous models.

Findings

Radiative feedback can support a quasi-static atmosphere around protoplanets below ~6 Jupiter masses.

Including radiative feedback changes the predicted population of planets versus brown dwarfs.

Without radiative feedback, low-mass clumps migrate inward rapidly, often disrupting.

Abstract

It is well known that massive protoplanetary disc are gravitationally unstable beyond tens of AU from their parent star. The eventual fate of the self-gravitating gas clumps born in the disc is currently not understood, although the range of uncertainty is well known. If clumps migrate inward rapidly, they are tidally disrupted, which may leave behind giant or terrestrial like planets. On the other hand, if clumps migrate less rapidly, they tend to accrete gas, becoming proto brown dwarfs or low mass companions to the parent star. Here we argue that radiative feedback of contracting clumps (protoplanets) on their discs is an important effect that has been overlooked in previous calculations. We show analytically that temperature in clump's vicinity may be high enough to support a quasi-static atmosphere if the clump mass is below a critical value, $M_{\rm cr} \sim 6$ Jupiter masses ($M_J$). This may arrest further gas accretion onto the clump and thus promote formation of planets rather than low mass companions. We use numerical simulations to evaluate these analytical conclusions by studying migration and accretion of gas clumps as a function of their initial mass, $M_i$. Simulations neglecting the radiative preheating effect show that gas clumps with mass less than $\sim 2 M_J$ migrate inward rapidly; more massive clumps result in low mass companions. In contrast, simulations that include radiative preheating from the clump show that clumps as massive as $8 M_J$ migrate inward rapidly and end up tidally disrupted in the inner disc. We conclude that, with other parameters being equal, previous simulations neglecting radiative feedback from self-gravitating clumps over-estimated the population of brown dwarfs and low mass stellar companions and under-estimated the population of planets.