The Newborn Planet Population Emerging from Ring-Like Structures in Discs

Authors

Giuseppe Lodato, Università degli Studi di Milano
Giovanni Dipierro, University of Leicester
Enrico Ragusa, Università degli Studi di Milano
Feng Long, Peking University
Gregory J. Herczeg, Peking University
Ilaria Pascucci, University of Arizona
Paola Pinilla, University of Arizona
Carlo F. Manara, European Southern Observatory
Marco Tazzari, University of Cambridge
Yao Liu, Max Planck Institute for Astronomy
Gijs D. Mulders, NASA Nexus for Exoplanet System Science
Daniel Harsono, Leiden University
Yann Boehler, University Grenoble Alpes
François Ménard, University Grenoble Alpes
Doug Johnstone, NRC Herzberg Astronomy and Astrophysic
Colette Salyk, Vassar College
Gerrit van der Plas, University Grenoble Alpes
Sylvie Cabrit, Sorbonne Université
Suzan Edwards, Smith CollegeFollow
William J. Fischer, Space Telescope Science Institute Baltimore
Nathan Hendler, University of Arizona
Brunella Nisini, INAF-Osservatorio Astronomico di Roma
Elisabetta Rigliaco, INAF-Osservatorio Astronomico di Padova
Henning Avenhaus, Max Planck Institute for Astronomy
Andrea Banzatti, University of Arizona
Michael Gully-Santiago, NASA Ames Research Center and Bay Area Environmental Research Institute

Document Type

Article

Publication Date

6-2019

Publication Title

Monthly Notices of the Royal Astronomical Society

Abstract

ALMA has observed a plethora of ring-like structures in planet-forming discs at distances of 10–100 au from their host star. Although several mechanisms have been invoked to explain the origin of such rings, a common explanation is that they trace new-born planets. Under the planetary hypothesis, a natural question is how to reconcile the apparently high frequency of gap-carving planets at 10–100 au with the paucity of Jupiter-mass planets observed around main-sequence stars at those separations. Here, we provide an analysis of the new-born planet population emerging from observations of gaps in discs, under the assumption that the observed gaps are due to planets. We use a simple estimate of the planet mass based on the gap morphology, and apply it to a sample of gaps recently obtained by us in a survey of Taurus with ALMA. We also include additional data from recent published surveys, thus analysing the largest gap sample to date, for a total of 48 gaps. The properties of the purported planets occupy a distinctively different region of parameter space with respect to the known exo-planet population, currently not accessible through planet finding methods. Thus, no discrepancy in the mass and radius distribution of the two populations can be claimed at this stage. We show that the mass of the inferred planets conforms to the theoretically expected trend for the minimum planet mass needed to carve a dust gap. Finally, we estimate the separation and mass of the putative planets after accounting for migration and accretion, for a range of evolutionary times, finding a good match with the distribution of cold Jupiters.

Keywords

accretion, accretion discs, planets and satellites: formation, protoplanetary discs.

Volume

486

Issue

1

First Page

453

Last Page

461

DOI

doi.org/10.1093/mnras/stz913

Rights

© 2019 The Author(s) Published by Oxford University Press on behalf of the Royal Astronomical Society

Comments

Archived as published.

Recommended Citation

Lodato, Giuseppe; Dipierro, Giovanni; Ragusa, Enrico; Long, Feng; Herczeg, Gregory J.; Pascucci, Ilaria; Pinilla, Paola; Manara, Carlo F.; Tazzari, Marco; Liu, Yao; Mulders, Gijs D.; Harsono, Daniel; Boehler, Yann; Ménard, François; Johnstone, Doug; Salyk, Colette; van der Plas, Gerrit; Cabrit, Sylvie; Edwards, Suzan; Fischer, William J.; Hendler, Nathan; Nisini, Brunella; Rigliaco, Elisabetta; Avenhaus, Henning; Banzatti, Andrea; and Gully-Santiago, Michael, "The Newborn Planet Population Emerging from Ring-Like Structures in Discs" (2019). Astronomy: Faculty Publications, Smith College, Northampton, MA.
https://scholarworks.smith.edu/ast_facpubs/11