Measurement of Cohesion in Asteroid Regolith Materials

A study has been initiated to examine cohesive forces in asteroid materials to contribute to a better understanding of low density bodies such as asteroids and Phobos, and assist in exploration missions involving interaction with their surface material. The test specimen used in this study was a lig...

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Hauptverfasser:	Kleinhenz, Julie E., Gaier, James R., Waters, Deborah L., Harvey, Ralph, Zeszut, Zoe, Carreno, Brandon, Shober, Patrick
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Sprache:	eng
Schlagworte:	Lunar And Planetary Science And Exploration
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creator	Kleinhenz, Julie E. Gaier, James R. Waters, Deborah L. Harvey, Ralph Zeszut, Zoe Carreno, Brandon Shober, Patrick
description	A study has been initiated to examine cohesive forces in asteroid materials to contribute to a better understanding of low density bodies such as asteroids and Phobos, and assist in exploration missions involving interaction with their surface material. The test specimen used in this study was a lightly weathered CM2 meteorite which is spectroscopically similar to Type C (carbonaceous) asteroids, and thought to have representative surface chemistry. To account for sample heterogeneity, adhesion forces were measured between the CM2 sample and its five primary mineral phase components. These adhesive forces bound the range of cohesive force that can be expected for the bulk material. All materials were characterized using a variety of optical and spectroscopic methods. Adhesive forces on the order of 50 to 400 μN were measured using a torsion balance in an ultrahigh vacuum chamber. The mineral samples exhibited clearly different adhesive strengths in the following hierarchy: Serpentine > Siderite > Bronzite > Olivine ≈ Fe-Ni.
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title	Measurement of Cohesion in Asteroid Regolith Materials
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