火星地质年代学与未来仪器的发展。

Geochronology on Mars and the Development of Future Instrumentation.

机构信息

Solar System Exploration Division, NASA Goddard Space Flight Center, Greenbelt, Maryland.

Division of Geological and Planetary Sciences, California Institute of Technology, Pasadena, California.

出版信息

Astrobiology. 2019 Nov;19(11):1303-1314. doi: 10.1089/ast.2018.1871. Epub 2019 Jul 30.

DOI:10.1089/ast.2018.1871

PMID:31361510

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6818483/

Abstract

We review the geochronology experiments conducted by the Mars Science Laboratory mission's Curiosity rover to understand when the Gale Crater rocks formed, underwent alteration, and became exposed to cosmogenic radiation. These experiments determined that the detrital minerals in the sedimentary rocks of Gale are ∼4 Ga, consistent with their origin in the basalts surrounding the crater. The sedimentary rocks underwent fluid-moderated alteration 2 Gyr later, which may mark the closure of aqueous activity at Gale Crater. Over the past several million years, wind-driven processes have dominated, denuding the surfaces by scarp retreat. The Curiosity measurements validate radiometric dating techniques on Mars and guide the way for future instrumentation to make more precise measurements that will further our understanding of the geological and astrobiological history of the planet.

摘要

我们回顾了火星科学实验室任务中的好奇号漫游车进行的地质年代学实验，以了解盖尔陨石坑岩石的形成、经历的变化以及暴露于宇宙辐射的时间。这些实验确定，盖尔陨石坑沉积岩中的碎屑矿物约为 40 亿年，与它们起源于陨石坑周围的玄武岩一致。20 亿年前，这些沉积岩经历了流体调节的变化，这可能标志着盖尔陨石坑水活动的结束。在过去的几百万年里，风驱动的过程占据主导地位，通过悬崖后退使表面剥蚀。好奇号的测量结果验证了火星上的放射性测年技术，并为未来的仪器指引了方向，以便进行更精确的测量，从而进一步了解这颗行星的地质和天体生物学历史。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8c05/6818483/fe02de081fd5/fig-1.jpg

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火星地质年代学与未来仪器的发展。

Geochronology on Mars and the Development of Future Instrumentation.

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