Title:
Mean-Motion Resonances as a Source for Infalling Comets toward beta Pictoris
Authors:
Beust, Herve; Morbidelli, Alessandro
Affiliation:
AA(Observatoire de Grenoble, Universite J. Fourier, Grenoble Cedex 9, France),
AB(Observatoire de la
Cote d'Azur, Le Mont Gros, Nice Cedex 4, France)
Journal:
Icarus, Volume 120, Issue 2, pp. 358-370. (Icarus Homepage)
Publication Date:
04/1996
Origin:
ICAR
Abstract Copyright:
(c) 1996: Academic Press
Bibliographic Code:
1996Icar..120..358B
Abstract
Repeated time-variable redshifted absorption features in the spectrum
of beta Pictoris (beta Pic) have been attributed to
comet-like bodies falling toward the star, when evaporating in its
immediate vicinity. This model explains now a large number of
observational characteristics, but the exact mechanism that could generate
these numerous star-grazers is still controversial, even
if planetary perturbations are thought to be the basic process. The
different models proposed up to now are here reviewed, and we
discuss in particular a recent one, involving the effect of secular
resonances in the beta Pic system. We stress that it seems highly
improbable that such a mechanism could apply to the beta Pic case,
because the extremely strong power of secular resonances is
connected to the very specific structure of the Solar System. Therefore,
the secular resonance mechanism is highly non-generic.
Conversely, we propose a model involving the eccentricity-pumping effect
of mean-motion resonances with a massive planet on a
moderately eccentric orbit. We show in particular that the 4:1 mean-motion
resonance is a very active source of star-grazers as
soon as the eccentricity of the perturbing planet is >~0.05, while
the 3:1 mean-motion resonance is less efficient. We stress that
this mechanism is very generic. These theoretical predictions are confirmed
by numerical integrations using the Extended Schubart
Integrator. The time-scale of the process is discussed, and we show
that if the eccentricity of the perturbing planet fluctuates, due
to secular perturbations, this time-scale is compatible with the age
of beta Pic's system.