| Issue |
A&A
Volume 471, Number 2, August IV 2007
|
|
|---|---|---|
| Page(s) | 717 - 730 | |
| Section | Planets and planetary systems | |
| DOI | https://doi.org/10.1051/0004-6361:20067029 | |
| Published online | 18 June 2007 | |
Thermal forces on planetary ring particles: application to the main system of Saturn *,**
1
Institute of Astronomy, Charles University, V Holešovičkách 2, 18000 Prague, Czech Republic e-mail: vokrouhl@mbox.cesnet.cz
2
Department of Space Studies, Southwest Research Institute, 1050 Walnut St., Boulder, CO 80302, USA
Received:
26
December
2006
Accepted:
31
May
2007
Context.The motion of small particles in planetary rings is affected in the long-term by radiation forces. While the Poynting-Robertson effect has been extensively discussed and applied to the dynamics of micron-sized ring particles, studies of thermal self-acceleration of particles are only in their infancy.
Aims.We extend the pioneering work of Rubincam (2006, Icarus 184, 532) by a more thorough analytical formulation of both planetary and solar thermal forces on ring particles.
Methods.Within a sparse disk model we analytically compute both seasonal and diurnal variants of the thermal forces and we demonstrate that the diurnal effect components vanish for a sample of rapidly rotating particles with randomly oriented spin axes. For sufficiently slowly rotating ring particles, though, these diurnal components might significantly modify the expected planetocentric secular drift rates of their orbits. We also take into account the orbital effects of Poynting-Robertson drag that begin to dominate the thermal forces for particles with sizes ≤5 mm. Our formulation of the Poynting-Robertson drag is the first to account properly for the influence of the planetary shadow.
Results.We critically review the previous
suggestion that Saturn's A and B ring boundaries might
correlate with radiative null-torque orbits of small particles.
Using the best estimates of optical and thermal parameters
of Saturn's ring particles, we show that the millimetre to several
centimetre size particles mostly drift inward to the planet with
a characteristic radial speed 
cm/s,
corresponding to drift across the whole main ring system in ~
years if the effects of inter-particle collisions
are neglected. The radial speed is comparable to, or even larger than,
the effective radial
drift rate of small particles due to redistribution of collisional
ejecta from micrometeoroid impacts. Therefore, radiation forces
may be important for estimating the evolution
timescales of Saturn's rings as derived from the ballistic transport
theory. We propose that, in addition to collisional coagulation,
radiation forces may efficiently remove centimetre-sized particles
and thus help explain the observed paucity of these particles
in Saturn's rings.
A population of particles with spin axes aligned with normal to the
disk plane, if it exists, would experience a net outward drift provided
their rotation rate is larger than their orbital frequency.
Key words: planets: rings / radiation mechanisms: non-thermal
© ESO, 2007
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