Dust accumulation near the magnetospheric truncation of protoplanetary discs around T Tauri stars

ABSTRACT The prevalence of short-period super-Earths that are independent of host metallicity challenges the theoretical construction of their origin. We propose that dust trapping in the global pressure bump induced by magnetospheric truncation in evolved protoplanetary discs (PPDs) around T Tauri...

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Published in:Monthly notices of the Royal Astronomical Society 2022-03, Vol.510 (4), p.5246-5265
Main Authors: Li(李日新), Rixin, Chen(陈逸贤), Yi-Xian, Lin(林潮), Douglas N C
Format: Article
Language:English
Subjects:
Accretion disks
Accumulation
Coagulation
Cosmic dust
Diffusion rate
Dust
Extrasolar planets
Magnetospheres
Metallicity
Planet formation
Planetary evolution
Protoplanetary disks
Star formation
Stellar evolution
T Tauri stars
Turbulent diffusion
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Summary:ABSTRACT The prevalence of short-period super-Earths that are independent of host metallicity challenges the theoretical construction of their origin. We propose that dust trapping in the global pressure bump induced by magnetospheric truncation in evolved protoplanetary discs (PPDs) around T Tauri stars offers a promising formation mechanism for super-Earths, where the host metallicity is already established. To better understand this planet-forming scenario, we construct a toy inner disc model and focus on the evolution of dust trapped in the bump, taking into account the supply from drifting pebbles and loss due to funnel flows. We develop an implicit coagulation–fragmentation code, rubble, and perform a suite of simulations to evolve the local dust-size distributions. Our study for the first time considers dust feedback effect on turbulent diffusion in this kind of model. We report that efficient dust growth and significant accumulation of dust mass are possible in less turbulent disc with sturdier solids and with faster external supply, laying out a solid foundation for further growth towards planetesimals and planetary embryos. We further find that, depending on the dominant process, solid mass may predominantly accumulate in cm-sized grains or particles in runaway growth, indicating different ways of forming planetesimals. Furthermore, these various outcomes show different efficiencies in saving dust from funnel flows, suggesting that they may be distinguishable by constraining the opacity of funnel flows. Also, these diverse dust behaviours may help to explain the observed dipper stars and rapidly varying shadows in PPDs.
ISSN:0035-8711
1365-2966
DOI:10.1093/mnras/stab3677