Volatile Sample Return in the Solar System

Bulletin of the AAS Pub Date : 2020-07-29 DOI:10.3847/25C2CFEB.D94F26C7

S. Milam, J. Dworkin, J. Elsila, D. Glavin, P. Gerakines, J. Mitchell, K. Nakamura-messenger, M. Neveu, L. Nittler, J. Parker, E. Quintana, S. Sandford, J. Schlieder, R. Stroud, M. Trainer, M. Wadhwa, A. Westphal, M. Zolensky, D. Bodewits, S. Clemett

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引用次数: 1

Abstract

We advocate for the realization of volatile sample return from various destinations including: small bodies, the Moon, Mars, ocean worlds/satellites, and plumes. As part of recent mission studies (e.g., Comet Astrobiology Exploration SAmple Return (CAESAR) and Mars Sample Return), new concepts, technologies, and protocols have been considered for specific environments and cost. Here we provide a plan for volatile sample collection and identify the associated challenges with the environment, transit/storage, Earth re-entry, and curation. Laboratory and theoretical simulations are proposed to verify sample integrity during each mission phase. Sample collection mechanisms are evaluated for a given environment with consideration for alteration. Transport and curation are essential for sample return to maximize the science investment and ensure pristine samples for analysis upon return and after years of preservation. All aspects of a volatile sample return mission are driven by the science motivation: isotope fractionation, noble gases, organics and prebiotic species; plus planetary protection considerations for collection and for the sample. The science value of sample return missions has been clearly demonstrated by previous sample return programs and missions. Sample return of volatile material is key to understanding (exo)planet formation, evolution, and habitability. Returning planetary volatiles poses unique and potentially severe technical challenges. These include preventing changes to samples between (and including) collection and analyses, and meeting planetary protection requirements.

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太阳系中挥发性样品的返回

我们主张从各种目的地实现挥发性样品返回，包括:小天体、月球、火星、海洋世界/卫星和羽流。作为最近任务研究的一部分(例如，彗星天体生物学探索样本返回(CAESAR)和火星样本返回)，已经考虑了特定环境和成本的新概念，技术和协议。在这里，我们提供了一个挥发性样品收集的计划，并确定了与环境、运输/储存、重返地球和管理相关的挑战。提出了实验室和理论模拟来验证每个任务阶段的样品完整性。在考虑变化的情况下，对给定环境的样本收集机制进行评估。运输和管理对于样品返回至关重要，以最大限度地提高科学投资，并确保原始样品在返回和保存多年后进行分析。挥发性样品返回任务的所有方面都受到科学动机的驱动:同位素分馏，稀有气体，有机物和益生元物种;加上收集和样品的行星保护考虑。样品返回任务的科学价值已被以往的样品返回计划和任务清楚地证明。挥发性物质样本的返回是理解(系外)行星形成、演化和可居住性的关键。返回地球的挥发物带来了独特的、潜在的严峻技术挑战。这些措施包括防止样品在采集和分析之间(包括)发生变化，以及满足行星保护要求。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Bulletin of the AAS

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