Expectations for Crater Size and Photometric Evolution from the Deep Impact Collision

Issue Title: Deep Impact Mission: Looking Beneath the Surface of a Cometary Nucleus The NASA Discovery Deep Impact mission involves a unique experiment designed to excavate pristine materials from below the surface of comet. In July 2005, the Deep Impact (DI) spacecraft, will release a 360 kg probe...

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Bibliographic Details
Published in:Space science reviews 2005-03, Vol.117 (1-2), p.207-239
Main Authors: Schultz, Peter H, Ernst, Carolyn M, Anderson, Jennifer LB
Format: Article
Language:English
Subjects:
Physical properties
Porosity
Spacecraft
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Summary:Issue Title: Deep Impact Mission: Looking Beneath the Surface of a Cometary Nucleus The NASA Discovery Deep Impact mission involves a unique experiment designed to excavate pristine materials from below the surface of comet. In July 2005, the Deep Impact (DI) spacecraft, will release a 360 kg probe that will collide with comet 9P/Tempel 1. This collision will excavate pristine materials from depth and produce a crater whose size and appearance will provide fundamental insights into the nature and physical properties of the upper 20 to 40 m. Laboratory impact experiments performed at the NASA Ames Vertical Gun Range at NASA Ames Research Center were designed to assess the range of possible outcomes for a wide range of target types and impact angles. Although all experiments were performed under terrestrial gravity, key scaling relations and processes allow first-order extrapolations to Tempel 1. If gravity-scaling relations apply (weakly bonded particulate near-surface), the DI impact could create a crater 70 m to 140 m in diameter, depending on the scaling relation applied. Smaller than expected craters can be attributed either to the effect of strength limiting crater growth or to collapse of an unstable (deep) transient crater as a result of very high porosity and compressibility. Larger then expected craters could indicate unusually low density (< 0.3 g cm^sup -3^) or backpressures from expanding vapor. Consequently, final crater size or depth may not uniquely establish the physical nature of the upper 20 m of the comet. But the observed ejecta curtain angles and crater morphology will help resolve this ambiguity. Moreover, the intensity and decay of the impact "flash" as observed from Earth, space probes, or the accompanying DI flyby instruments should provide critical data that will further resolve ambiguities.[PUBLICATION ABSTRACT]
ISSN:0038-6308
1572-9672
DOI:10.1007/s11214-005-3383-7