TY - JOUR
T1 - Dust rings trap protoplanets on eccentric orbits and get consumed by them
AU - Velasco-Romero, David A.
AU - Masset, Frédéric S.
AU - Morbidelli, Alessandro
AU - Benítez-Llambay, Pablo
AU - Krapp, Leonardo
AU - Lega, Elena
N1 - Publisher Copyright:
© 2024 The Author(s).
PY - 2024/9/1
Y1 - 2024/9/1
N2 - We study the orbital evolution and mass growth of protoplanets with masses M ∈ [0.1–8] M in the vicinity of a dusty ring, using three-dimensional numerical simulations with a two-fluid model and nested-meshes. We find two stable, eccentric orbits that lock the planet in the ring vicinity, thereby inhibiting its migration and allowing it to accrete dust from the ring. One of these orbits has an eccentricity comparable to the aspect ratio of the gaseous disc and has its periastron within the ring, enabling intermittent accretion during each pass. The other orbit has a smaller eccentricity and an apoastron slightly inside the ring. A planet locked at the outer orbit efficiently accretes from the ring and can reach the critical mass for runaway gas accretion on time-scales 105 yr (for a 10 M dust ring at 10 au), while a planet locked at the inner orbit has a slower growth and might not supersede the super-Earth stage over the disc lifetime. While in our runs a low-mass embryo forming within the ring eventually joins the outer orbit, it is likely that the path taken depends on the specific details of the ring. The trapping on the outer orbit arises from an intermittent, strong thermal force at each passage through the ring, where the accretion rate spikes. It is insensitive to uncertainties that plague models considering planets trapped on circular orbits in rings. It is highly robust and could allow a growing planet to follow an expanding ring over large distances.
AB - We study the orbital evolution and mass growth of protoplanets with masses M ∈ [0.1–8] M in the vicinity of a dusty ring, using three-dimensional numerical simulations with a two-fluid model and nested-meshes. We find two stable, eccentric orbits that lock the planet in the ring vicinity, thereby inhibiting its migration and allowing it to accrete dust from the ring. One of these orbits has an eccentricity comparable to the aspect ratio of the gaseous disc and has its periastron within the ring, enabling intermittent accretion during each pass. The other orbit has a smaller eccentricity and an apoastron slightly inside the ring. A planet locked at the outer orbit efficiently accretes from the ring and can reach the critical mass for runaway gas accretion on time-scales 105 yr (for a 10 M dust ring at 10 au), while a planet locked at the inner orbit has a slower growth and might not supersede the super-Earth stage over the disc lifetime. While in our runs a low-mass embryo forming within the ring eventually joins the outer orbit, it is likely that the path taken depends on the specific details of the ring. The trapping on the outer orbit arises from an intermittent, strong thermal force at each passage through the ring, where the accretion rate spikes. It is insensitive to uncertainties that plague models considering planets trapped on circular orbits in rings. It is highly robust and could allow a growing planet to follow an expanding ring over large distances.
KW - hydrodynamics
KW - planets and satellites: formation
KW - planet–disc interactions
KW - protoplanetary discs
UR - http://www.scopus.com/inward/record.url?scp=85201461265&partnerID=8YFLogxK
U2 - 10.1093/mnras/stae1835
DO - 10.1093/mnras/stae1835
M3 - Article
AN - SCOPUS:85201461265
SN - 0035-8711
VL - 533
SP - 807
EP - 825
JO - Monthly Notices of the Royal Astronomical Society
JF - Monthly Notices of the Royal Astronomical Society
IS - 1
ER -