TY - JOUR
T1 - Migration and evolution of extrasolar planets
AU - Trilling, D. E.
AU - Benz, W.
AU - Guillot, T.
AU - Lunine, J. I.
AU - Hubbard, W. B.
AU - Burrows, A.
N1 - Funding Information:
Acknowledgements. The authors wish to thank Didier Samnon, Chris Chyba, and Doug Lin for stimulating discussions. D. T. is supported by an NSF Graduate Research FelIowship. T. G. is supported by a Training and Mobility of Researchers grant from the European Community. This work is supported in part by the NASA Origins of Solar Systems Program, grant NAG5-4051. D. T. thanks the University of Arizona Theoretical Astrophysics Program for travel support.
PY - 1999
Y1 - 1999
N2 - Giant planets in circumstellar disks can migrate inward from their initial (formation) positions at several AUs. Inward radial migration of the planet is caused by torques between the planet and the disk; outward radial migration of the planet is caused by torques between the planet and the spinning star, and by torques due to Roche lobe overflow and consequent mass loss from the planet. We present self-consistent numerical considerations of the problem of migrating giant planets by summing torques on planets for various physical parameters of the disk and of planets. We find that Jupiter-mass planets can stably arrive and survive at small heliocentric distances, thus reproducing observed properties of some of the recently discovered extra-solar planets. The range of fates of massive planets is broad, and some perish by losing all their mass onto the central star during Roche lobe overflow, while others survive for the lifetime of the central star. Surviving planets cluster into two groups when examined in terms of final mass and final heliocentric distance: those which have lost mass and those which have not. Some of the observed extrasolar planets fall into each of these two exclusive classes. We also find that there is an inner boundary for planets' final heliocentric distances, caused by tidal torques with the central star. Planets in small orbits are shown to be stable against atmospheric loss.
AB - Giant planets in circumstellar disks can migrate inward from their initial (formation) positions at several AUs. Inward radial migration of the planet is caused by torques between the planet and the disk; outward radial migration of the planet is caused by torques between the planet and the spinning star, and by torques due to Roche lobe overflow and consequent mass loss from the planet. We present self-consistent numerical considerations of the problem of migrating giant planets by summing torques on planets for various physical parameters of the disk and of planets. We find that Jupiter-mass planets can stably arrive and survive at small heliocentric distances, thus reproducing observed properties of some of the recently discovered extra-solar planets. The range of fates of massive planets is broad, and some perish by losing all their mass onto the central star during Roche lobe overflow, while others survive for the lifetime of the central star. Surviving planets cluster into two groups when examined in terms of final mass and final heliocentric distance: those which have lost mass and those which have not. Some of the observed extrasolar planets fall into each of these two exclusive classes. We also find that there is an inner boundary for planets' final heliocentric distances, caused by tidal torques with the central star. Planets in small orbits are shown to be stable against atmospheric loss.
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U2 - 10.1016/S1464-1917(99)00090-2
DO - 10.1016/S1464-1917(99)00090-2
M3 - Article
AN - SCOPUS:0033386519
SN - 1464-1917
VL - 24
SP - 553
EP - 556
JO - Physics and Chemistry of the Earth, Part C: Solar, Terrestrial and Planetary Science
JF - Physics and Chemistry of the Earth, Part C: Solar, Terrestrial and Planetary Science
IS - 5
ER -