Prebiotic chemistry and atmospheric warming of early Earth by an active young Sun (original) (raw)

References

  1. Barrett, G. C. & Elmore, D. T. Amino Acids and Peptides (Cambridge Univ. Press, 1998).
    Book Google Scholar
  2. Ringwood, A. E. Chemical composition of the terrestrial planets. Geochim. Cosmochim. Acta 30, 41–104 (1996).
    Article Google Scholar
  3. Summers, D. P., Basa, R. C. B., Khare, B. & Rodoni, D. Abiotic nitrogen fixation on terrestrial planets: reduction of NO to ammonia by FeS. Astrobiology 12, 107–114 (2012).
    Article Google Scholar
  4. Kasting, J. F. Bolide impacts and the oxidation state of carbon in the Earth’s early atmosphere. Orig. Life Evol. Biosph. 20, 199–231 (1990).
    Article Google Scholar
  5. Maehara, H. et al. Superflares on solar-type stars. Nature 485, 478–481 (2012).
    Article Google Scholar
  6. Shibayama, T. et al. Superflares on solar-type stars observed with Kepler. I. Statistical properties of superflares. Astrophys. J. Suppl. Ser. 209, 5 (2013).
    Article Google Scholar
  7. Gopalswamy, N. et al. Properties of ground level enhancement events and the associated solar eruptions during solar cycle 23. Space Sci. Rev. 171, 23–60 (2012).
    Article Google Scholar
  8. Tsurutani, B. T., Smith, E. J., Pyle, K. R. & Simpson, J. A. Energetic protons accelerated at corotating shocks - Pioneer 10 and 11 observations from 1 to 6 AU. J. Geophys. Res. 87, 7389–7404 (1982).
    Article Google Scholar
  9. Emslie, A. G. et al. Global energetics of thirty-eight large solar eruptive events. Astrophys. J. 759, 71 (2012).
    Article Google Scholar
  10. Miyake, F., Nagaya, K., Masuda, K. & Nakamura, T. A signature of cosmic-ray increase in AD 774–775 from tree rings in Japan. Nature 486, 240–242 (2012).
    Article Google Scholar
  11. Miyake, F., Masuda, K. & Nakamura, T. Another rapid event in the carbon-14 content of tree rings. Nature Commun. 4, 1748 (2013).
    Article Google Scholar
  12. Tsurutani, B. T., Gonzales, W. D., Lakhina, G. S. & Alex, S. The extreme magnetic storm of 1–2 September 1859. J. Geophys. Res. 108, 1268 (2003).
    Article Google Scholar
  13. Vidotto, A. A. et al. Stellar magnetism: empirical trends with age and rotation. Month. Not. R. Astron. Soc. 441, 2361–2374 (2014).
    Article Google Scholar
  14. Airapetian, V., Glocer, A. & Danchi, W. in Proc. 18th Cambridge Workshop on Cool Stars, Stellar Systems, and the Sun (eds van Belle, G. & Harris, H.) 257–268 (2015).
    Google Scholar
  15. Airapetian, V. S. & Usmanov, A. V. Reconstructing the solar wind from its early history to current epoch. Astrophys. J. 817, L24–L30 (2016).
    Article Google Scholar
  16. Tarduno, J., Blackman, E. G. & Mamajek, E. E. Detecting the oldest geodynamo and attendant shielding from the solar wind: implications for habitability. Phys. Earth Planet. Inter. 233, 68–87 (2014).
    Article Google Scholar
  17. Liu, Y. D. et al. Observations of an extreme storm in interplanetary space caused by successive coronal mass ejections. Nature Commun. 5, 3481 (2014).
    Article Google Scholar
  18. Gronoff, G. et al. The precipitation of keV energetic oxygen ions at Mars and their effects during the comet Siding Spring approach. Geophys. Res. Lett. 41, 4844–4850 (2014).
    Article Google Scholar
  19. Cnossen, I. et al. Habitat of early life: solar X-ray and UV radiation at Earth’s surface 4–3.5 billion years ago. J. Geophys. Res. 112, E02008 (2007).
    Article Google Scholar
  20. Claire, M. W. et al. The evolution of solar flux from 0.1 nm to 160 μm: quantitative estimates for planetary studies. Astrophys. J. 757, 95 (2012).
    Article Google Scholar
  21. Mewaldt, R. A. Energy spectra, composition, and other properties of ground-level events during solar cycle 23. Space Sci. Rev. 171, 97–120 (2012).
    Article Google Scholar
  22. Goldblatt, C. et al. Nitrogen-enhanced greenhouse warming on early Earth. Nature Geosci. 2, 891–896 (2009).
    Article Google Scholar
  23. Nna-Mvondo, D., Navarro-González, R., Raulin, F. & Coll, P. Nitrogen fixation by corona discharge on the early precambrian Earth. 2005. Orig. Life Evol. Biosph. 35, 401–409 (2005).
    Article Google Scholar
  24. Brandvold, D. K., Martinez, P. & Hipsh, R. Field measurements of O3 and N2O produced from a corona discharge. Atmos. Environ. 30, 973–976 (1996).
    Article Google Scholar
  25. Gough, D. O. Solar interior structure and luminosity variations. Solar Phys. 74, 21–34 (1981).
    Article Google Scholar
  26. Kasting, J. F. Early Earth: faint young Sun redux. Nature 464, 687–689 (2010).
    Article Google Scholar
  27. Wordsworth, R. & Pierrehumbert, R. Hydrogen–nitrogen greenhouse warming in Earth’s early atmosphere. Science 339, 64–67 (2013).
    Article Google Scholar
  28. Rosing, M. T., Bird, D. K., Sleep, N. H. & Bjerrum, C. J. No climate paradox under the faint early Sun. Nature 464, 744–747 (2010).
    Article Google Scholar
  29. Miyakawa, S., Cleaves, H. J. & Miller, S. L. The cold origin of life: B. implications based on pyrimidines and purines produced from frozen ammonium cyanide solutions. Orig. Life Evol. Biosph. 32, 209–218 (2002).
    Article Google Scholar
  30. Powell, K. G., Roe, P. L., Linde, T. J., Gombosi, T. I. & De Zeeuw, D. L. A solution-adaptive upwind scheme for ideal magnetohydrodynamics. J. Comp. Phys. 154, 284–309 (1999).
    Article Google Scholar
  31. de Zeeuw, D. L. et al. Coupling of a global MHD code and an inner magnetospheric model: initial results. J. Geophys. Res. 109, A12219 (2004).
    Article Google Scholar
  32. Ridley, A. J. et al. University of Michigan MHD results of the geospace global circulation model metrics challenge. J. Geophys. Res. 107, 1290 (2002).
    Article Google Scholar
  33. Ngwira, C. M., Pulkkinen, A., Kuznetsova, M. M. & Glocer, A. Modeling extreme “Carrington-type” space weather events using three-dimensional global MHD simulations. J. Geophys. Res. 119, 4456–4474 (2014).
    Article Google Scholar

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