Asteroid surface impact sampling: dependence of the cavity morphology and collected mass on projectile shape

Asteroid surface impact sampling: dependence of the cavity morphology and collected mass on projectile shape

In-situ exploration and remote thermal infrared observation revealed that a large fraction of Solar System small bodies should be covered with granular regolith. The complex and varied geology of the regolith layer may preserve the historical records of the surface modification and topographic evolu...

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Veröffentlicht in:Scientific reports 2017-08, Vol.7 (1), p.10004-10, Article 10004
Hauptverfasser: Cheng, Bin, Yu, Yang, Baoyin, Hexi
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Asteroids
Excavation
Exploration
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Gravity
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Morphology
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Sampling
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Science (multidisciplinary)
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description In-situ exploration and remote thermal infrared observation revealed that a large fraction of Solar System small bodies should be covered with granular regolith. The complex and varied geology of the regolith layer may preserve the historical records of the surface modification and topographic evolution experienced by asteroids, especially cratering processes, in which the projectile shape plays a crucial role. Regarding the impact sampling scheme, the projectile-shape dependence of both the cavity morphology and the collected mass remains to be explored. This paper studies the process of the low-speed impact sampling on granular regolith using projectiles of different shapes. The results demonstrate that the projectile shape significantly influences the excavation stage, forming cavities with different morphologies, i.e., cone-shaped, bowl-shaped and U-shaped. We further indicate that the different velocity distributions of the ejecta curtains due to the various projectile shapes result in various amounts of collected mass in sampler canister, regarding which the 60° conical projectile exhibits preferable performance for impact sampling scheme. The results presented in this article are expected to reveal the dependence of the excavation process on projectile shape under micro gravity and provide further information on the optimal designs of impact sampling devices for future sample-return space missions.
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We further indicate that the different velocity distributions of the ejecta curtains due to the various projectile shapes result in various amounts of collected mass in sampler canister, regarding which the 60° conical projectile exhibits preferable performance for impact sampling scheme. 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subjects 639/33/34/861
639/33/445/215
639/33/445/848
704/445/848
Asteroids
Excavation
Exploration
Geology
Gravity
Humanities and Social Sciences
Morphology
multidisciplinary
Sampling
Science
Science (multidisciplinary)
title Asteroid surface impact sampling: dependence of the cavity morphology and collected mass on projectile shape
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