30 research outputs found
Resonant capture of multiple planet systems under dissipation and stable orbital configurations
Migration of planetary systems caused by the action of dissipative forces may
lead the planets to be trapped in a resonance. In this work we study the
conditions and the dynamics of such resonant trapping. Particularly, we are
interested in finding out whether resonant capture ends up in a long-term
stable planetary configuration. For two planet systems we associate the
evolution of migration with the existence of families of periodic orbits in the
phase space of the three-body problem. The family of circular periodic orbits
exhibits a gap at the 2:1 resonance and an instability and bifurcation at the
3:1 resonance. These properties explain the high probability of 2:1 and 3:1
resonant capture at low eccentricities. Furthermore, we study the resonant
capture of three-planet systems. We show that such a resonant capture is
possible and can occur under particular conditions. Then, from the migration
path of the system, stable three-planet configurations, either symmetric or
asymmetric, can be determined.Comment: 10 ages, 13 figures, 5th Ph.D. School on Mathematical Modeling for
Complex System
Continuation and stability deduction of resonant periodic orbits in three dimensional systems
In dynamical systems of few degrees of freedom, periodic solutions consist
the backbone of the phase space and the determination and computation of their
stability is crucial for understanding the global dynamics. In this paper we
study the classical three body problem in three dimensions and use its dynamics
to assess the long-term evolution of extrasolar systems. We compute periodic
orbits, which correspond to exact resonant motion, and determine their linear
stability. By computing maps of dynamical stability we show that stable
periodic orbits are surrounded in phase space with regular motion even in
systems with more than two degrees of freedom, while chaos is apparent close to
unstable ones. Therefore, families of stable periodic orbits, indeed, consist
backbones of the stability domains in phase space.Comment: Proceedings of the 6th International Conference on Numerical Analysis
(NumAn 2014). Published by the Applied Mathematics and Computers Lab,
Technical University of Crete (AMCL/TUC), Greec
Multi-Planet Destabilisation and Escape in Post-Main Sequence Systems
Discoveries of exoplanets orbiting evolved stars motivate critical
examinations of the dynamics of -body systems with mass loss. Multi-planet
evolved systems are particularly complex because of the mutual interactions
between the planets. Here, we study the underlying dynamical mechanisms which
can incite planetary escape in two-planet post-main sequence systems. Stellar
mass loss alone is unlikely to be rapid and high enough to eject planets at
typically-observed separations. However, the combination of mass loss and
planet-planet interactions can prompt a shift from stable to chaotic regions of
phase space. Consequently, when mass loss ceases, the unstable configuration
may cause escape. By assuming a constant stellar mass loss rate, we utilize
maps of dynamical stability to illustrate the distribution of regular and
chaotic trajectories in phase space. We show that chaos can drive the planets
to undergo close encounters, leading to the ejection of one planet. Stellar
mass loss can trigger the transition of a planetary system from a stable to
chaotic configuration, subsequently causing escape. We find that mass loss
non-adiabatically affects planet-planet interaction for the most massive
progenitor stars which avoid the supernova stage. For these cases, we present
specific examples of planetary escape.Comment: Accepted for publication in MNRAS (2013
Resonant planetary dynamics: Periodic orbits and long-term stability
Many exo-solar systems discovered in the last decade consist of planets
orbiting in resonant configurations and consequently, their evolution should
show long-term stability. However, due to the mutual planetary interactions a
multi-planet system shows complicated dynamics with mostly chaotic
trajectories. We can determine possible stable configurations by computing
resonant periodic trajectories of the general planar three body problem, which
can be used for modeling a two-planet system. In this work, we review our model
for both the planar and the spatial case. We present families of symmetric
periodic trajectories in various resonances and study their linear horizontal
and vertical stability. We show that around stable periodic orbits there exist
regimes in phase space where regular evolution takes place. Unstable periodic
orbits are associated with the existence of chaos and planetary
destabilization.Comment: Proceedings of 10th HSTAM International Congress on Mechanics,
Chania, Crete, Greece, 25-27 May, 201