Boulders and ponds on the Asteroid 433 Eros

Abstract There are ∼300 features on the Asteroid 433 Eros that morphologically resemble ponds (flat-floored and sharply embaying the bounding depression in which they sit). Because boulders on Eros are apparently eroding in place and because ponds with associated boulders tend to be larger than ponds without blocks, we propose that ponds form from thermally disaggregated and seismically flattened boulder material, under the assumption that repeated day/night cycling causes material fatigue that leads to erosion of the boulders. Results from a simple boulder emplacement/thermal erosion model with boulders emplaced in a few discrete events (i.e., large impacts) match well the observed size distribution. Under this scenario, the subtle color differences of ponds (somewhat bluer than the rest of the surface) might be due to some combination of less space-weathered material and density stratification of silicate-rich chondrules and more metal-rich matrix from a disaggregated boulder. Volume estimates of ponds derived from NEAR Laser Rangefinder profiles are consistent with what can be supplied by boulders. Ponds are also observed to be concentrated in regions of low slope and high elevation, which suggests the presence of a less mobile regolith and thus a contrast in the resistance to seismic shaking between the pond material and the material that makes up the bounding depression. Future tests include shake-table experiments and temperature cycling (fatigue) of ordinary chondrites to test the thermal erosion mechanism.

[1]  Clark R. Chapman,et al.  NEAR Encounter with Asteroid 253 Mathilde: Overview , 1999 .

[2]  N. Izenberg,et al.  Imaging of Small-Scale Features on 433 Eros from NEAR: Evidence for a Complex Regolith , 2001, Science.

[3]  Peter C. Thomas,et al.  Gravity, Tides, and Topography on Small Satellites and Asteroids: Application to Surface Features of the Martian Satellites , 1993 .

[4]  Jennifer M. Brown,et al.  Hydrothermal systems in small ocean planets. , 2007, Astrobiology.

[5]  Li,et al.  NEAR at eros: imaging and spectral results , 2000, Science.

[6]  R. Arvidson,et al.  Cosmic ray exposure ages of features and events at the apollo landing sites , 1975 .

[7]  L. Nittler,et al.  Minor element evidence that Asteroid 433 Eros is a space-weathered ordinary chondrite parent body , 2006 .

[8]  David E. Smith,et al.  Laser Altimetry of Small-Scale Features on 433 Eros from NEAR-Shoemaker , 2001, Science.

[9]  S. Murchie,et al.  The geology of 433 Eros , 2002 .

[10]  William D. Callister,et al.  Materials Science and Engineering: An Introduction , 1985 .

[11]  Randolph L. Kirk,et al.  Eros: Shape, Topography, and Slope Processes , 2002 .

[12]  N. Izenberg,et al.  The landing of the NEAR-Shoemaker spacecraft on asteroid 433 Eros , 2001, Nature.

[13]  H. Melosh Impact Cratering: A Geologic Process , 1986 .

[14]  Andrew F. Cheng,et al.  Small-Scale Topography of 433 Eros from Laser Altimetry and Imaging , 2000 .

[15]  Hajime Yano,et al.  Fundamentally distinct outcomes of asteroid collisional evolution: Itokawa and Eros , 2007 .

[16]  Kevin Hall,et al.  The role of thermal stress fatigue in the breakdown of rock in cold regions , 1999 .

[17]  G. Flynn PHYSICAL PROPERTIES OF METEORITES AND INTERPLANETARY DUST PARTICLES: CLUES TO THE PROPERTIES OF THE METEORS AND THEIR PARENT BODIES , 2006 .

[18]  P. Thomas,et al.  Seismic resurfacing by a single impact on the asteroid 433 Eros , 2005, Nature.

[19]  R. Walker,et al.  Nuclear track studies of dynamic surface processes on the moon and the constancy of solar activity , 1971 .

[20]  M. Birlan,et al.  Solar wind as the origin of rapid reddening of asteroid surfaces , 2009, Nature.

[21]  S. Murchie,et al.  Shoemaker crater as the source of most ejecta blocks on the asteroid 433 Eros , 2001, Nature.

[22]  Richard Greenberg,et al.  Impact-Induced Seismic Activity on Asteroid 433 Eros: A Surface Modification Process , 2004, Science.

[23]  William D. Callister,et al.  Materials science and engineering : an introduction : student learning resources , 2003 .

[24]  Harry Y. McSween,et al.  SIZES AND MASSES OF CHONDRULES AND METAL-TROILITE GRAINS IN ORDINARY CHONDRITES : POSSIBLE IMPLICATIONS FOR NEBULAR SORTING , 1999 .

[25]  J. Veverka,et al.  Surface Expressions of Structural Features on Eros , 2002 .

[26]  J. Colwell,et al.  Electrostatic dust transport on Eros: 3-D simulations of pond formation , 2008 .

[27]  David P. O'Brien,et al.  The global effects of impact-induced seismic activity on fractured asteroid surface morphology , 2005 .

[28]  Angioletta Coradini,et al.  Dawn discovery mission to Vesta and Ceres: Present status , 2006 .

[29]  Eileen V. Ryan,et al.  On collisional disruption - Experimental results and scaling laws , 1990 .

[30]  J. Bell,et al.  Detection of Temperature-Dependent Spectral Variation on the Asteroid Eros and New Evidence for the Presence of an Olivine-Rich Silicate Assemblage , 2002 .

[31]  M. Horányi,et al.  Dust transport in photoelectron layers and the formation of dust ponds on Eros , 2005 .

[32]  M. Robinson,et al.  The nature of ponded deposits on Eros , 2001, Nature.

[33]  William K. Hartmann,et al.  Impact experiments 3 : catastrophic fragmentation of aggregate targets and relation to asteroids , 1991 .

[34]  Clark R. Chapman,et al.  Ponded deposits on asteroid 433 Eros , 2002 .