The debris disk – terrestrial planet connection

The debris disk – terrestrial planet connection

The eccentric orbits of the known extrasolar giant planets provide evidence that most planet-forming environments undergo violent dynamical instabilities. Here, we numerically simulate the impact of giant planet instabilities on planetary systems as a whole. We find that populations of inner rocky a...

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Veröffentlicht in:Proceedings of the International Astronomical Union 2010-10, Vol.6 (S276), p.82-88
Hauptverfasser: Raymond, Sean N., Armitage, Philip J., Moro-Martín, Amaya, Booth, Mark, Wyatt, Mark C., Armstrong, John C., Mandell, Avi M., Selsis, Franck
Format: Artikel
Sprache:eng
Schlagworte:
Astrophysics
Contributed Papers
Debris
Disks
Dynamical systems
Dynamics
Earth and Planetary Astrophysics
Extrasolar planets
Instability
Physics
Planets
Sciences of the Universe
Simulation
Solar and Stellar Astrophysics
Solar system
Stability
Terrestrial planets
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Zusammenfassung:The eccentric orbits of the known extrasolar giant planets provide evidence that most planet-forming environments undergo violent dynamical instabilities. Here, we numerically simulate the impact of giant planet instabilities on planetary systems as a whole. We find that populations of inner rocky and outer icy bodies are both shaped by the giant planet dynamics and are naturally correlated. Strong instabilities – those with very eccentric surviving giant planets – completely clear out their inner and outer regions. In contrast, systems with stable or low-mass giant planets form terrestrial planets in their inner regions and outer icy bodies produce dust that is observable as debris disks at mid-infrared wavelengths. Fifteen to twenty percent of old stars are observed to have bright debris disks (at λ ~ 70μm) and we predict that these signpost dynamically calm environments that should contain terrestrial planets.
ISSN:1743-9213
1743-9221
DOI:10.1017/S1743921311019983