Bombardment history of the Saturn system

We analyze crater distributions on Voyager images of Saturn's satellites and develop models of relative cratering rates on these bodies based on orbital dynamics. Our goal is to construct a history of satellite bombardment, disruption, and resurfacing in the Saturn system. Our observations concentrate on Rhea, the largest and best imaged of Saturn's airless moons. We divide the portion of Rhea imaged at high resolution into 44 latitude-longitude quadrats for counting purposes. Detailed analysis of the spatial distribution of craters shows no statistically significant evidence for local endogenic resurfacing on Rhea. The apparent spatial variability in the distribution of small craters is strongly correlated with lighting geometry and hence unlikely to have resulted from geologic processes. Also, we find that the spatial distribution of craters on Rhea with diameters D ≥ 32 km is in fact more uniform than a majority of random distribution produced by Monte Carlo simulations. We interpret this observation as possible evidence that the surface has approached (but not necessarily reached) saturation equilibrium for craters with diameters up to 32 km. (Impacts on a heavily cratered surface will tend to preferentially obliterate craters in areas of randomly produced crater clustering, leading to an increase in spatial uniformity.) Craters with D ≥ 64 km on Rhea have densitites significantly below any proposed saturation equilibrium density; therefore they probably represent a production function. The size-frequency relationship of these large craters on Rhea is well fit by the curve log10NL = −2.73 log10D − 0.064, where NL is the number of craters larger than D km per km. The analogous relationship for Iapetus is log10NL = −2.70 log10D + 0.109. Iapetus is also clearly not saturated at large crater diameters. On Mimas, as on Rhea, the spatial distribution of craters shows no statistically significant evidence for spatial variability, and large craters appear to be present at densities below those expected for saturation equilibrium. We compute relative cratering rates and collision energies for heliocentric projectiles impacting Saturn's moons, taking into account gravitational focusing by the planet. Using crater scaling laws, we project the large crater distributions seen on Rhea and Iapetus to expected integrated impact fluxes on other moons. Disruption probabilities of Saturn's inner moons estimated by this method vary by a factor of ∼2 depending on what crater scaling law we use and whether the impactors are predominantly Saturn-family comets or long-period comets. Computed disruption probabilities are 3–7 times higher when scaled to lapetus's cratering record than to Rhea's. This could be due to Iapetus' surface being older than Rhea's, in which case the Iapetus scaling is correct; alternatively, Iapetus may have been cratered by a long-lived population of Saturn-orbiting debris which did not penetrate inside the orbit of Titan, in which case Rhea's record should be used. These uncertainties not withstanding, we calculate disruption probabilities significantly smaller than those of Smith et al. (1982). Our results are consistent with Mimas and larger moons being original aggregates and the smaller irregularly shaped bodies being collisional fragments. Our results also constrain theories advocating recent formation of Saturn's rings from satellite disruption. We conclude that (1) there is no evidence for local geologic resurfacing on Rhea or Mimas; (2) either the surface of Iapetus is older than that of Rhea, or Iapetus was bombarded by a population of Saturn-orbiting debris which did not extend inward to Rhea; (3) if the heavily cratered surfaces in the Saturn system have indeed reached saturation at small diameters, the cratering record on Saturn's moons may be due to a single population of impactors dominated by small bodies; (4) Rhea, Mimas, and Iapetus are not saturated with craters at large crater diameters; thus observed densities of large craters may be used to evaluate satellite disruption probabilities; (5) Saturn's classical satellites are probably original aggregates dating from the epoch of Saturn's formation, as opposed to products of repeated disruption and reaccretion during more recent history; and (6) it is very unlikely that Saturn's rings were formed within the last 109 years by the disruption of a single moon.

[1]  S. Tremaine,et al.  Evolution of the Janus-Epimetheus coorbital resonance due to torques from Saturn's ring , 1985 .

[2]  J. Plescia Geology of Dione , 1983 .

[3]  W. Hartmann Planet formation - Mechanism of early growth , 1978 .

[4]  A. H. Marcus Comparison of equilibrium size distributions for lunar craters , 1970 .

[5]  J. Connerney,et al.  A micrometeorite erosion model and the age of Saturn's rings , 1987 .

[6]  J. Lissauer,et al.  Ring torque on Janus and the melting of Enceladus , 1984 .

[7]  K. Holsapple,et al.  A material-strength model for apparent crater volume. , 1979 .

[8]  G. Neukum,et al.  Planetocentric versus heliocentric impacts in the Jovian and Saturnian Satellite System , 1984 .

[9]  S. Squyres,et al.  The evolution of Enceladus , 1983 .

[10]  R. Strom Crater Populations on Mimas, Dione and Rhea , 1981 .

[11]  D. Gault,et al.  Laboratory simulation of pelagic asteroidal impact Atmospheric injection, benthic topography, and the surface wave radiation field , 1982 .

[12]  W. Hartmann Does crater “saturation equilibrium” occur in the solar system? , 1984 .

[13]  J. Boyce,et al.  Impact cratering history of the Saturnian satellites , 1985 .

[14]  Steven W. Squyres,et al.  The martian hemispheric dichotomy may be due to a giant impact , 1984, Nature.

[15]  Peter Goldreich,et al.  The Dynamics of Planetary Rings , 1982 .

[16]  J. Plescia Cratering history of the Uranian satellites: Umbriel, Titania, and Oberon , 1987 .

[17]  R. Strom,et al.  Limits on large-crater production and obliteration on Callisto , 1981 .

[18]  K. A. Holsapple,et al.  Scaling laws for the catastrophic collisions of asteroids , 1986 .

[19]  T V Johnson,et al.  Encounter with saturn: voyager 1 imaging science results. , 1981, Science.

[20]  K. Holsapple,et al.  Estimates of crater size for large-body impact: Gravity-scaling results , 1982 .

[21]  A. Woronow A general cratering-history model and its implications for the lunar highlands , 1978 .

[22]  R. H. Brown,et al.  Voyager 2 in the Uranian System: Imaging Science Results , 1986, Science.

[23]  D. L. Anderson,et al.  The Origin of the Moon , 1972, Nature.

[24]  R. Strom The solar system cratering record: Voyager 2 results at Uranus and implications for the origin of impacting objects , 1987 .

[25]  G. Fielder,et al.  Further Tests for Randomness of Lunar Craters , 1967 .

[26]  K. A. Holsapple,et al.  On the Scaling of Crater Dimensions 2. Impact Processes , 1982 .

[27]  A. Woronow Crater saturation and equilibrium - A Monte Carlo simulation. [lunar distribution , 1976 .

[28]  E. Whitaker The Lunar Procellarum Basin , 1980 .

[29]  J. Pollack,et al.  Estimates of the size of the particles in the rings of saturn and their cosmogonic implications , 1973 .

[30]  A. Cook,et al.  An explanation of the light curve of Iapetus , 1970 .

[31]  J. Boyce,et al.  Crater densities and geological histories of Rhea, Dione, Mimas and Tethys , 1982, Nature.

[32]  William K. Hartmann,et al.  Satellite-Sized Planetesimals and Lunar Origin , 1975 .

[33]  A multivariate immigration with multiple death process and applications to lunar craters. , 1967, Biometrika.

[34]  W. Benz,et al.  Planetary Collision Calculations: Origin of Mercury , 1987 .

[35]  J. Boyce,et al.  Crater numbers and geological histories of Iapetus, Enceladus, Tethys and Hyperion , 1983, Nature.

[36]  J. L. Mitchell,et al.  A New Look at the Saturn System: The Voyager 2 Images , 1982, Science.

[37]  Charles F. Yoder,et al.  How tidal heating in Io drives the galilean orbital resonance locks , 1979, Nature.

[38]  P. Cadogan Oldest and largest lunar basin? , 1974, Nature.

[39]  Donald E. Gault,et al.  Saturation and Equilibrium Conditions for Impact Cratering on the Lunar Surface: Criteria and Implications , 1970 .