EXTREMOPHILES as Astrobiological Models. Группа авторов
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Название: EXTREMOPHILES as Astrobiological Models

Автор: Группа авторов

Издательство: John Wiley & Sons Limited

Жанр: Физика

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isbn: 9781119593102

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СКАЧАТЬ Mars [2.36] [2.37] (Figure 2.2).

      In 2000, Christensen et al. [2.24] [2.25] reported the occurrence of extensive outcrops of hematite in the region of Terra Meridiani. This mineral is abundant in Rio Tinto as the result of the maturation of ferric acidic minerals. This enigmatic enrichment led to the selection of Meridiani as the landing site for the Opportunity rover in 2004. During the exploration of this area, Opportunity detected hematite occurring in spheroidal concretions that were named blueberries. However, the most intriguing and revealing finding was the abundance of sulfates [2.93] [2.101] [2.80] where the main mineral phase was jarosite, as detected by Mössbauer spectroscopy on board the Opportunity [2.63]. Later on, it was observed that the acidic sulfates were very extensive in different Mars regions, supporting the idea that Mars had been exposed to a low-pH episode lasting hundreds of millions of years [2.79] [2.33] [2.29], whose origin has been related to the weathering of metallic sulfides [2.34] [2.112]. Very recently, the formation of iron sulfides associated with hydrothermal materials that are similar to the hydrothermal rocks of the Rio Tinto basement was reported [2.78]. This suggests that the biogeochemical cycles of the putative biosphere that could have emerged on Mars might have been dominated by S and Fe metabolism, as is observed in Rio Tinto.

      The preservation of different biosignatures in the ancient acidic materials of Rio Tinto strongly supports that, if life emerged on Mars, traces of its activity in acidic deposits are just as likely to remain as they are in materials that formed under mildly neutral conditions in the red planet [2.28]. Given that acidic environments were abundant in the Late Noachian to Hesperian ages (more than 3.5 billion years ago), the next astrobiological missions should increase the chances of finding traces of life on the red planet by seeking them in acidic deposits.