Frontiers in Astronomy and Space Sciences (May 2022)

Formamide-Based Post-impact Thermal Prebiotic Synthesis in Simulated Craters: Intermediates, Products and Mechanism

  • Martin Ferus,
  • Antonín Knížek,
  • Antonín Knížek,
  • Lukáš Petera,
  • Lukáš Petera,
  • Adam Pastorek,
  • Adam Pastorek,
  • Jana Hrnčířová,
  • Jana Hrnčířová,
  • Luboš Jankovič,
  • Ondřej Ivanek,
  • Jiří Šponer,
  • Jiří Šponer,
  • Anna Křivková,
  • Anna Křivková,
  • Homa Saeidfirozeh,
  • Svatopluk Civiš,
  • Elias Chatzitheodoridis,
  • Klaudia Mráziková,
  • Klaudia Mráziková,
  • Lukáš Nejdl,
  • Lukáš Nejdl,
  • Franz Saija,
  • Judit E. Šponer,
  • Judit E. Šponer,
  • Giuseppe Cassone

DOI
https://doi.org/10.3389/fspas.2022.882145
Journal volume & issue
Vol. 9

Abstract

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Influx of matter from impacting meteoroids and hydrothermal crater weathering are important factors modifying the rock and mineral inventory of young planets undergoing heavy bombardment. These processes may have influenced not only the geochemical environment of, e.g., early Mars and other planets, but also the peculiar prebiotic chemistry on early Earth. Here, we present a synergistic experimental and computational investigation of the intermediates of chemical reactions of the formamide-based synthesis of canonical and non-canonical nucleobases by thermochemistry in hot hydrothermal crater environments. We put our findings into context with previously investigated plasma-initiated synthesis occuring directly during impact. Both processes result into the formation of all canonical nucleobases, hypoxanthine, purine, and into the onset of the simplest amino acid glycine. Furthermore, it turns out that radical species such as CN and H play a key role in the plasma-assisted impact chemistry. However, post-impact thermochemistry is essential for the origin of formamidine and 2-aminoacetonitrile, intermediate species detected in this study by means of FTIR spectroscopy.

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