Orbital stability of compact three-planet systems, II: Post-instability impact behaviour
Orbital stability of compact three-planet systems, II: Post-instability impact behaviour
Recent observational missions have uncovered a significant number of compact multi-exoplanet systems. The tight orbital spacing of these systems has led to much effort being applied to the understanding of their stability; however, a key limitation of the majority of these studies is the termination of simulations as soon as the orbits of two planets cross. In this work we explore the stability of compact, three-planet systems, and continue our simulations all the way to the first collision of planets to yield a better understanding of the lifetime of these systems. We perform over 25 000 integrations of a Sun-like star orbited by three Earth-like secondaries for up to a billion orbits to explore a wide parameter space of initial conditions in both the co-planar and inclined cases, with a focus on the initial orbital spacing. We calculate the probability of collision over time and determine the probability of collision between specific pairs of planets. We find systems that persist for over 108 orbits after an orbital crossing and show how the post-instability survival time of systems depends upon the initial orbital separation, mutual inclination, planetary radius, and the closest encounter experienced. Additionally, we examine the effects of very small changes in the initial positions of the planets upon the time to collision and show the effect that the choice of integrator can have upon simulation results. We generalize our results throughout to show both the behaviour of systems with an inner planet initially located at 1 and 0.25 AU.
Methods: numerical, Planets and satellites: Dynamical evolution and stability
6181-6194
Bartram, Peter
c17fb8a1-0034-4778-b216-e54ae5d89c17
Wittig, Alexander
3a140128-b118-4b8c-9856-a0d4f390b201
Lissauer, Jack J.
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Gavino, Sacha
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Urrutxua, Hodei
ec73b9d7-654f-4db7-9ff3-68ad05543cfe
22 May 2021
Bartram, Peter
c17fb8a1-0034-4778-b216-e54ae5d89c17
Wittig, Alexander
3a140128-b118-4b8c-9856-a0d4f390b201
Lissauer, Jack J.
e7990f64-b993-45c4-b365-0f03b46b94d9
Gavino, Sacha
6be13fbd-90ed-4305-aa4f-d90251dbaef7
Urrutxua, Hodei
ec73b9d7-654f-4db7-9ff3-68ad05543cfe
Bartram, Peter, Wittig, Alexander, Lissauer, Jack J., Gavino, Sacha and Urrutxua, Hodei
(2021)
Orbital stability of compact three-planet systems, II: Post-instability impact behaviour.
Monthly Notices of the Royal Astronomical Society, 506 (4), .
(doi:10.1093/mnras/stab1465).
Abstract
Recent observational missions have uncovered a significant number of compact multi-exoplanet systems. The tight orbital spacing of these systems has led to much effort being applied to the understanding of their stability; however, a key limitation of the majority of these studies is the termination of simulations as soon as the orbits of two planets cross. In this work we explore the stability of compact, three-planet systems, and continue our simulations all the way to the first collision of planets to yield a better understanding of the lifetime of these systems. We perform over 25 000 integrations of a Sun-like star orbited by three Earth-like secondaries for up to a billion orbits to explore a wide parameter space of initial conditions in both the co-planar and inclined cases, with a focus on the initial orbital spacing. We calculate the probability of collision over time and determine the probability of collision between specific pairs of planets. We find systems that persist for over 108 orbits after an orbital crossing and show how the post-instability survival time of systems depends upon the initial orbital separation, mutual inclination, planetary radius, and the closest encounter experienced. Additionally, we examine the effects of very small changes in the initial positions of the planets upon the time to collision and show the effect that the choice of integrator can have upon simulation results. We generalize our results throughout to show both the behaviour of systems with an inner planet initially located at 1 and 0.25 AU.
Text
stab1465
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Accepted/In Press date: 5 May 2021
Published date: 22 May 2021
Additional Information:
Publisher Copyright:
© The Author(s) 2021.
Copyright:
Copyright 2021 Elsevier B.V., All rights reserved.
Keywords:
Methods: numerical, Planets and satellites: Dynamical evolution and stability
Identifiers
Local EPrints ID: 452541
URI: http://eprints.soton.ac.uk/id/eprint/452541
ISSN: 1365-2966
PURE UUID: 284f2bbd-754d-4e3c-a6c5-c4e4361974e4
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Date deposited: 11 Dec 2021 11:26
Last modified: 17 Mar 2024 03:47
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Author:
Peter Bartram
Author:
Jack J. Lissauer
Author:
Sacha Gavino
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