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The Taurid Complex: Giant Comet Origin?

Published online by Cambridge University Press:  12 April 2016

D.I. Steel
Affiliation:
Department of Physics and Mathematical Physics University of Adelaide, G.P.O.Box 498, Adelaide, SA 5001, Australia Department of Physics, University of OxfordKeble Road, Oxford, 0X1 3RH, United Kingdom
D.J. Asher
Affiliation:
Department of Physics, University of OxfordKeble Road, Oxford, 0X1 3RH, United Kingdom
S.V.M. Clube
Affiliation:
Department of Physics, University of OxfordKeble Road, Oxford, 0X1 3RH, United Kingdom

Abstract

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The formation and evolution of the Taurid Complex of interplanetary objects is modelled on the basis of the parent being a giant comet which entered the inner solar system some time in the past 10,000-20,000 years. The orbital element distributions for the presently-observed meteor showers are discussed in terms of how these can constrain any model for the origin of the overall complex. As a baseline model we present results from the numerical integrations of fictitious meteoroids released from a comet over ten millenia, this comet having initial elements similar to those derived from a backwards integration of P/Encke. Large relative velocities at perihelion, above those feasible in conventional ejection scenarios, are necessary; we ascribe these to jetting of organics and other volatiles soon after release. Such a model gives a good first-order fit to the observed orbits, although additional processes (cometary splitting or asteroidal collisions) appear also to be necessary to explain the Taurids.

Type
Meteoroids and Meteor Streams
Copyright
Copyright © Kluwer 1991

References

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