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The photochemistry of the paleoatmosphere

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Summary

The ideas of Harold Urey on the origin and evolution of the atmosphere have dominated thinking in this area for 3 decades. Recent progress in this area is reviewed, with particular emphasis on photochemical modeling studies of atmospheric evolution. Research into the paleoatmosphere can be divided into 3 distinct areas: (1) The photochemistry/chemistry of the prebiological paleoatmosphere, (2) the evolution of oxygen and the transition to an oxidizing atmosphere, and (3) the origin and evolution of ozone. Photochemical calculations indicate that the stability of a heavily reducing paleoatmosphere of CH4—NH3 was extremely shortlived, if such a prebiological atmosphere ever existed at all. A more mildly reducing early atmosphere of CO2—N2 is favored by photochemical considerations. Recent calculations of O2 in the prebiological paleoatmosphere vary from less than 10−14 of present atmospheric level (PAL) to 10−1 PAL. Clearly, additional work is indicated. The evolution of O3 as a function of O2 level has been investigated with increasingly detailed photochemical models that have included the photochemistry/chemistry of the oxygen, hydrogen, nitrogen, carbon, and chlorine species, as well as the effects of eddy transport, the rainout of water-soluble species, dry deposition and lightning as a source of trace atmospheric gases.

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References

  • Abelson PH (1966) Chemical events on the primitive Earth. Proc Natl Acad Sci (USA) 55:1365–1372

    Google Scholar 

  • Ackermann M (1971) In: Fiocco G (ed) Ultraviolet solar radiation related to mesospheric processes. Mesospheric models and related experiments. D. Reidel, Dordrecht, Holland, pp 149–159

    Google Scholar 

  • Bates DR, Nicolet M (1950) The photochemistry of atmospheric water vapor. J Geophys Res 55:301–327

    Google Scholar 

  • Berkner LV, Marshall LC (1965) On the origin and rise of oxygen concentration in the Earth's atmosphere. J Atmos Sci 22:225–261

    Google Scholar 

  • Blake AJ, Carver JH (1977) The evolutionary role of atmospheric ozone. J Atmos Sci 34:720–728

    Google Scholar 

  • Brinkmann RT (1969) Dissociation of water vapor and evolution of oxygen in the terrestrial atmosphere. J Geophys Res 74:5255–5368

    Google Scholar 

  • Canuto VM, Levine JS, Augustsson TR, Imhoff CL (1982) Ultraviolet radiaton from the young sun and levels of oxygen and ozone in the prebiological paleoatmosphere. Nature (in press)

  • Carver JH (1981) Prebiotic atmospheric oxygen levels. Nature 292:136–318

    Google Scholar 

  • Chang S (1979) In: Neugebauer M, Yeomens DK, Brandt JC (eds) Comets: Cosmic connections with carbonaceous meteorites, interstellar molecules and the origin of life. Space missions to comets, NASA Reference Publication 2089, National Technical Information Service, Springfield, Virginia, pp 59–112

    Google Scholar 

  • Chapman S (1930) A theory of upper atmospheric ozone. Mem Roy Meteor Soc 3:103–125

    Google Scholar 

  • Cloud PE (1968) Atmospheric and hydrospheric evolution on the primitive Earth. Science 160:729–736

    Google Scholar 

  • Crutzen PJ (1970) The influence of nitrogen oxides on the atmospheric ozone content. Quart J Roy Meteor Soc 96:320–325

    Google Scholar 

  • Crutzen PJ (1971) Ozone production rates in oxygen-hydrogen-nitrogen oxide atmosphere. J Geophys Res 76:7311–7327

    Google Scholar 

  • Des Marais D (1981) Stable isotope measurements of geothermal emanations. Research and Technology Annual Report 1981, NASA TM-81333, Ames Research Center, Moffett, California, p 6

    Google Scholar 

  • Gold T (1979) Terrestrial sources of carbon and earthquake outgassing. J Petrol Geol 1:3–19

    Google Scholar 

  • Haldane JBS (1928) The origin of life. Rationalist Ann 148:3–10

    Google Scholar 

  • Hart MH (1978) The evolution of the atmosphere of the Earth. Icarus 33:23–39

    Google Scholar 

  • Hart MH (1979) Was the pre-biotic atmosphere of the Earth heavily reducing? Origins Life 9:261–266

    Google Scholar 

  • Henderson-Sellers A, Schwartz AW (1980) Chemical evolution and ammonia in the early Earth's atmosphere. Nature 287:526–528

    Google Scholar 

  • Hesstvedt E, Henriksen SE, Hjartarson H (1974) On the development of an aerobic atmosphere. A model experiment. Geophysica Norvegica 31:1–8

    Google Scholar 

  • Holland HD (1962) In: Engle AEJ, James HL, Leonard BF (eds) Model for the evolution of the Earth's atmosphere. Petrologic studies: A volume in honor of A.F. Buddington. Geological Society of America, N.Y., pp 447–477

    Google Scholar 

  • Hunten DM (1973) The escape of light gases from planetary atmospheres. J Atmos Sci 30:1481–1494

    Google Scholar 

  • Johnston HS (1971) Reduction of stratospheric ozone by nitrogen oxide catalysts from SST exhaust. Science 173:517–522

    Google Scholar 

  • Kasting JF, Donahue TM (1980) The evolution of atmospheric ozone. J Geophys Res 85:3255, 3263

    Google Scholar 

  • Kasting JF, Walker JCG (1981) Limits on oxygen concentration in the prebiological atmosphere and the rate of abiotic fixation of nitrogen. J Geophys Res 86:1147–1158

    Google Scholar 

  • Kasting JF, Liu SC, Donahue TM (1979) Oxygen levels in the prebiological atmosphere. J Geophys Res 84:3097–3107

    Google Scholar 

  • Katsumori M (1979) Photochemical-radiative equilibrium of the Earth's paleoatmosphere with various amounts of oxygen. J Meteor Soc Japan 57:243–252

    Google Scholar 

  • Kerr RA (1980) Origin of life: New ingredients suggested. Science 210:42–43

    Google Scholar 

  • Knauth LP, Epstein S (1976) Hydrogen and oxygen isotope ratios in nodular and bedded cherts. Geochim Cosmochim Acta 40:1095–1108

    Google Scholar 

  • Kuhn WR, Atreya SK (1979) Ammonia photolysis and the greenhouse effect in the primordial atmosphere of the Earth. Icarus 37:207–213

    Google Scholar 

  • Lasaga AC, Holland HD, Dwyer MJ (1971) Primordial oil slick. Science 174:53–55

    Google Scholar 

  • Lazcano-Araujo A, Oró J (1981) In: Ponnamperuma C (ed) Cometary material and the origins of life on Earth. Comets and the origin of life. D. Reidel, Dordrecht, Holland, pp 191–225

    Google Scholar 

  • Levine JS (1978) In: Ponnamperuma C (ed) The evolution of H2O and CO2 on Earth and Mars. Comparative Planetology, Academic Press, New York, pp 165–182

    Google Scholar 

  • Levine JS (1980) Surface solar ultraviolet radiation for paleoatmospheric levels of oxygen and ozone. Origins Life 10:313–323

    Google Scholar 

  • Levine JS, Boughner RE (1979) The effect of paleoatmospheric ozone on surface temperature. Icarus 39:310–314

    Google Scholar 

  • Levine JS, Graedel TE (1981) Photochemistry in planetary atmospheres. EOS, Trans Amer Geophys Union 62:1177–1181

    Google Scholar 

  • Levine JS, Schryer DS (eds) (1978) Man's impact on the troposphere, NASA Reference Publication 1022, National Technical Information Service, Springfield, Virginia, p 376pp

    Google Scholar 

  • Levine JS, Hays PB, Walker JCG (1979a) The evolution and variability of atmospheric ozone over geological time. Icarus 39:295–309

    Google Scholar 

  • Levine JS, Hughes RE, Chameides WL, Howell WE (1979b) N2O and CO production by electric discharge: Atmospheric implications. Geophys Res Lett 6:557–559

    Google Scholar 

  • Levine JS, Augustsson TR, Hoell JM (1980a) The vertical distribution of tropospheric ammonia. Geophys Res Lett 7:317–320

    Google Scholar 

  • Levine JS, Boughner RE, Smith KA (1980b) Ozone, ultraviolet flux and temperature of the paleoatmosphere. Origins Life 10:199–213

    Google Scholar 

  • Levine JS, Augustsson TR, Boughner RE, Natarajan M, Sacks LJ (1981) In: Ponnamperuma C (ed) Comets and the photochemistry of the paleoatmosphere. Comets and the origin of life. D. Reidel, Dordrecht, Holland, pp 161–190

    Google Scholar 

  • Levine JS, Augustsson TR, Natarajan M (1982) The prebiological paleoatmosphere: Stability and composition. Origins Life 12 (in press)

  • Margulis L, Walker JCG, Rambler M (1976) Reassessment of roles of oxygen and ultraviolet light in Precambrian evolution. Nature 264:620–624

    Google Scholar 

  • McElroy MB, McConnell JC (1971) Nitrous oxide: A natural source of stratospheric NO. J Atmos Sci 28:1095–1098

    Google Scholar 

  • McGovern WE (1969) The primitive Earth: Thermal models of the upper atmosphere for a methane-dominated environment. J Atmos Sci 26:623–635

    Google Scholar 

  • Miller SL (1953) A production of amino acids under possible primitive Earth conditions. Science 117:528–529

    Google Scholar 

  • Miller SL, Urey HC (1959) Organic compound synthesis on the primitive earth. Science 130:245–251

    Google Scholar 

  • Morss DA, Kuhn WR (1978) Paleoatmospheric temperature structure. Icarus 33:40–49

    Google Scholar 

  • Oparin AI (1924) The origin of life. Izd Moskovskii Rabochii, Moscow

    Google Scholar 

  • Oró J (1961) Comets and the formation of biochemical compounds on the primitive Earth. Nature 190:389–390

    Google Scholar 

  • Pinto JP, Gladstone GR, Yung YL (1980) Photochemical production of formaldehyde in the Earth's primitive atmosphere. Science 210:183–185

    Google Scholar 

  • Rambler MB, Margulis L (1980) Bacterial response to ultraviolet irradiation under anerobiosis: Implications for Pre-Phanerozoic evolution. Science 210:638–640

    Google Scholar 

  • Ratner MI, Walker JCG (1972) Atmospheric ozone and the history of life. J Atmos Sci 29:803–808

    Google Scholar 

  • Rubey WW (1955) Development of the hydrosphere and atmosphere, with special composition of the early atmosphere. Geol Soc Amer Spec Paper: 62, Crust of the Earth, pp 631–650

    Google Scholar 

  • Sagan C, Mullen G (1972) Earth and Mars: Evolution of atmospheres and surface temperatures. Science 177:52–56

    Google Scholar 

  • Shimizu M (1976) Instability of a highly reducing atmosphere on the primitive Earth. Precamb Res 3:463–470

    Google Scholar 

  • Stolarski RS, Cicerone RJ (1975) Stratospheric chlorine: A possible sink for ozone. Canad J Chem 52:1610–1615

    Google Scholar 

  • Towe KM (1978) Early Precambrian oxygen: A case against photosynthesis. Nature 274:657–661

    Google Scholar 

  • Urey HC (1952a) The Planets: Their origin and development. Yale University Press, New Haven, p 245

    Google Scholar 

  • Urey HC (1952b) On the early chemical history of the Earth and the origin of life. Proc Natl Acad Sci (USA) 38:351–362

    Google Scholar 

  • Urey HC (1959) In: Flügge S (ed) The atmospheres of the planets. Encyclopedia of Physics, Vol VII. Springer, Berlin, Göttingen, Heidelberg, pp 363–418

    Google Scholar 

  • Vander Wood TB, Thiemens MH (1980) The fate of the hydroxyl radical in the Earth's primitive atmosphere and implications for the production of molecular oxygen. J Geophys Res 85:1605–1610

    Google Scholar 

  • Walker JCG (1976) In: Windley BF (ed) Implications for atmospheric evolution of the inhomogeneous accretion model of the origin of the Earth. The early history of the Earth. John Wiley and Sons, New York, pp 537–546

    Google Scholar 

  • Walker JCG (1977) Evolution of the atmosphere. MacMillan, New York, p 318pp

    Google Scholar 

  • Walker JCG (1978a) In: Ponnamperuma C (ed) Atmospheric evolution on the inner planets. Comparative planetology. Academic Press, New York, pp 141–164

    Google Scholar 

  • Walker JCG (1978b) Oxygen and hydrogen in the primitive atmosphere. Pure Appl Geophys 116:222–231

    Google Scholar 

  • Walker JCG (1978c) The early history of oxygen and ozone in the atmosphere. Pure Appl Geophys 117:498–512

    Google Scholar 

  • Yung YL, McElroy MB (1979) Fixation of nitrogen in the prebiotic atmosphere. Science 203:1002–1004

    Google Scholar 

Download references

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  1. Atmospheric Environmental Sciences Division, NASA Langley Research Center, 23665, Hampton, Virginia, USA

    Joel S. Levine

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Levine, J.S. The photochemistry of the paleoatmosphere. J Mol Evol 18, 161–172 (1982). https://doi.org/10.1007/BF01733042

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  • DOI: https://doi.org/10.1007/BF01733042

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