Escape dynamics and fractal basin boundaries in the planar Earth–Moon system

Escape dynamics and fractal basin boundaries in the planar Earth–Moon system

The escape of trajectories of a spacecraft, or comet or asteroid in the presence of the Earth–Moon system is investigated in detail in the context of the planar circular restricted three-body problem, in a scattering region around the Moon. The escape through the necks around the collinear points L...

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Bibliographic Details
Published in:Celestial mechanics and dynamical astronomy Vol. 120; no. 2; pp. 105 - 130
Main Authors: de Assis, Sheila C., Terra, Maisa O.
Format: Journal Article
Language:English
Published: Dordrecht Springer Netherlands 01-10-2014
Springer Nature B.V
Subjects:
Aerospace Technology and Astronautics
Astrophysics
Astrophysics and Astroparticles
Boundaries
Classical Mechanics
Dynamical Systems and Ergodic Theory
Earth
Geophysics/Geodesy
Moon
Orbits
Original Article
Physics
Physics and Astronomy
Spacecraft
Spatial distribution
Escape basins
Temporary capture
Chaotic scattering
Stickiness effects
Restricted three-body problem
Fractal basin boundaries
Escape dynamics
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Summary:The escape of trajectories of a spacecraft, or comet or asteroid in the presence of the Earth–Moon system is investigated in detail in the context of the planar circular restricted three-body problem, in a scattering region around the Moon. The escape through the necks around the collinear points L 1 and L 2 as well as the leaking produced by considering collisions with the Moon surface, taking the lunar mean radius into account, were considered. Given that different transport channels are available as a function of the Jacobi constant, four distinct escape regimes are analyzed. Besides the calculation of exit basins and of the spatial distribution of escape time, the qualitative dynamical investigation through Poincaré sections is performed in order to elucidate the escape process. Our analyses reveal the dependence of the properties of the considered escape basins with the energy, with a remarkable presence of fractal basin boundaries along all the escape regimes. Finally, we observe the plentiful presence of stickiness motion near stability islands which plays a remarkable role in the longest escape time behavior. The application of this analysis is important both in space mission design and study of natural systems, given that fractal boundaries are related with high sensitivity to initial conditions, implying in uncertainty between safe and unsafe solutions, as well as between escaping solutions that evolve to different phase space regions.
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ISSN:0923-2958
1572-9478
DOI:10.1007/s10569-014-9567-2