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5. On the Early Scattering Processes of the Outer Planets

Published online by Cambridge University Press:  12 April 2016

Abstract

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The gradual scattering of small bodies by the Jovian planets in the late stage of their accretion is simulated by Monte Carlo calculation. The effects of collisional interaction of the scattered planetesimals with the inner planets and asteroidal belt are estimated. The total mass influx injected into the terrestrial zones from the outer planetary zone could be appreciable; however, if the damping effects due to the mutual inelastic or catastrophic collisions among the small bodies were significant, the total mass influx would be greatly reduced. The origin of the cometary Oort cloud in relation to these scattering processes is also discussed. The calculation indicates that, in addition to Jupiter, Uranus and Neptune were likely to be the major contributors to the population of long-period comets if they originated from such scattering processes.

Type
Part VIII. The Origin of Comets
Copyright
Copyright © A.H. Delsemme 1977

References

Alfvén, H. 1970, Astrophys. Space Sci., 6, 161174.Google Scholar
Alfvén, H., and Arrhenius, G. 1970, Astrophys. Space Sci., 9, 333.CrossRefGoogle Scholar
Arnold, J. R. 1965, Astrophys. J., 141, 15361547.CrossRefGoogle Scholar
Davis, D. R. 1977, Paper No. 045-OT, presented at the 8th DPS Meeting of the American Astronomical Society, Honolulu, 19–22 January 1977.Google Scholar
Everhart, E. 1973, Astron. J., 78, 329337.Google Scholar
Everhart, E. 1976, in IAU Colloq. No. 25, The Study of Comets, Pt. 1, 445461 (ed. Donn, B., Mumma, M., Jackson, W., A’Heara, M. and Harrington, R.).Google Scholar
Ip, W.-H. 1974, Astrophys. Space Sci., 31, 5779.Google Scholar
Ip, W. -H. 1976a, unpublished result.Google Scholar
Ip, W. -H. 1976b, submitted to Icarus.Google Scholar
Ip, W. -H. 1976c, under preparation.Google Scholar
Hartmann, W. K. 1976, Icarus, 27, 553559.Google Scholar
Kaula, W. M. 1975, Icarus, 26, 115.Google Scholar
Kaula, W. M., and Bigeleisen, P. E. 1975, Icarus, 25, 1833 Google Scholar
Marsden, B. G., and Sekanina, Z. 1973, Astron. J., 78, 11181124.Google Scholar
Öpik, E. J. 1950, Proc. Royal Irish Acad., 54, Sec. A, 165199.Google Scholar
Öpik, E. J. 1961, Adv. Astron. Astrophys., 1, 219262.Google Scholar
Öpik, E. J. 1966, Adv. Astron. Astrophys., 4, 301336.CrossRefGoogle Scholar
Öpik, E. J. 1973, Astrophys. Space Sci., 21, 307398.CrossRefGoogle Scholar
Wetherill, G. W. 1967, J. Geophys. Res., 72, 24292444.Google Scholar
Wetherill, G. W. 1975a, Proc. Sov.-Am. Conf. on Cosmochem. 2. Moon and Planets, Moscow, June 1974.Google Scholar
Wetherill, G. W. 1975b, Proc. Sixth Lunar Sci. Conf., in press.Google Scholar