ALMA constraints on assembly of core accretion planets
Resolved dust continuum and CO line ALMA imaging, and in some cases detection of H α emission, hint that young massive planets are abundant at wide separations in protoplanetary discs. Here we show how these observations can probe the runaway phase of planetary growth in the Core Accretion theory. Planets in this phase have the right range of masses to account for the predominantly moderate contrast gaps and rings seen in ALMA observ ations. Ho we ver, we find that these planets gain mass and migrate inward very rapidly. As a result, the phase when they could produce gaps with properties similar to those observed is very short, i.e. t gap 0.1 Myr, independently of the disc viscosity parameter. This would require many tens to hundreds of gas giant planets to be born per ALMA system, violating the available mass budget of solids in realistic discs. This also predicts preponderance of discs with very wide gaps or complete inner disc holes, which is not observed. We show that suppression of both planet accretion and migration by a factor of at least ten is a possible solution to these serious problems. Future population synthesis models of planet formation should aim to address both exoplanetary data of older disc-less planetary systems and ALMA discs with embedded planets in one framework.
Funding
Astrophysics Research at the University of Leicester
Science and Technology Facilities Council
Find out more...Connecting theories and observations of planet formation
Science and Technology Facilities Council
Find out more...Ministry of Science and Higher Education of the Russian Federation under the grant 075-15-2020-780 (N13.1902.21.0039)
History
Author affiliation
College of Science & Engineering/Physics & AstronomyVersion
- VoR (Version of Record)
Published in
Monthly Notices of the Royal Astronomical SocietyVolume
516Issue
1Pagination
1250 - 1250Publisher
OXFORD UNIV PRESSissn
0035-8711eissn
1365-2966Copyright date
2022Available date
2024-03-14Publisher DOI
Language
EnglishPublisher version
Deposited by
Professor Sergei NayakshinDeposit date
2024-03-13Data Access Statement
The data underlying this article will be shared on reasonable request to the corresponding author.Rights Retention Statement
- No