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6 - Tectonics of small bodies

Published online by Cambridge University Press:  30 March 2010

By
Peter C. Thomas  and
Louise M. Prockter
Edited by
Thomas R. Watters  and
Richard A. Schultz
Peter C. Thomas
Affiliation:
Center for Radiophysics and Space Research, Cornell University, Ithaca
Louise M. Prockter
Affiliation:
Applied Physics Laboratory, Laurel
Thomas R. Watters
Affiliation:
Smithsonian Institution, Washington DC
Richard A. Schultz
Affiliation:
University of Nevada, Reno
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Summary

Summary

Solar system bodies smaller than ~200 km mean radius have little internal heat energy to drive tectonics typical of the terrestrial environment. Short-lived high stresses from impacts or long-term, low stresses are the primary shapers of these bodies. This chapter provides an overview of the basic features and processes that can be regarded as small-body tectonics.

Introduction: types of small bodies, their properties, and environments

Small bodies of the solar system are here taken to be those too small for gravitationally driven viscous relaxation to have determined their shapes. This definition restricts consideration to objects less than about 150 km radius (Johnson and McGetchin, 1973; Thomas, 1989). Within this definition are some dozens of satellites of planets, and thousands of asteroids, cometary nuclei, and Centaur and Kuiper-Edgeworth belt objects (Binzel et al., 2003). As of early 2006, spacecraft have visited small satellites, asteroids, and four cometary nuclei (Figure 6.1). Resolved information on these objects is dominated by the NEAR mission that orbited and then landed on 433 Eros, by images of the Martian satellites, Phobos and Deimos, and by images of comet Tempel 1 (A'Hearn et al., 2005). Radar images of near-Earth objects are beginning to show some details of asteroid shapes and surface features (Hudson et al., 2003). Meteorites provide small samples of asteroids, though only in the case of asteroid Vesta (larger than the size range considered here) are there positive connections of meteorite samples to a specific object (Binzel et al., 1993; Keil, 2002).

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Planetary Tectonics , pp. 233 - 263
Publisher: Cambridge University Press
Print publication year: 2009

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