Limited role for methane in the mid-Proterozoic greenhouse

Proceedings of the National Academy of Sciences of the United States of America

Volumn 113, Issue 41, 2016, Pages 11447-11452

  Olson, Stephanie L ^a   Reinhard, Christopher T ^a,b   Lyons, Timothy W ^a  

^a UNIVERSITY OF CALIFORNIA   (United States)

^b GEORGIA INSTITUTE OF TECHNOLOGY   (United States)

Author keywords

Boring billion; Faint young Sun; Methane; Oxygenation; Snowball Earth

Indexed keywords

METHANE; OXIDIZING AGENT;

ANAEROBIC METABOLISM; ARTICLE; ATMOSPHERE; BIOGEOCHEMICAL CYCLING; BIOSPHERE; CLIMATE; GLACIATION; GREENHOUSE; NEOPROTEROZOIC; NONHUMAN; PHOTOCHEMISTRY; PRIORITY JOURNAL; PROTEROZOIC; REDUCTION; SEA; STEADY STATE; WARMING; WEATHERING;

EID: 84991510667     PISSN: 00278424     EISSN: 10916490     Source Type: Journal    
DOI: 10.1073/pnas.1608549113     Document Type: Article

References (50)

1. Kasting JF (2005) Methane and climate during the Precambrian era. Precambrian Res 137(3):119-129.
2. Sagan C, Mullen G (1972) Earth and Mars: Evolution of atmospheres and surface temperatures. Science 177(4043):52-56.
3. Walker JCG, Hays PB, Kasting JF (1981) A negative feedback mechanism for the longterm stabilization of Earth's surface temperature. J Geophys Res 86(C10):9776-9782.
4. 4in the atmosphere of early Earth. J Geophys Res 105(E5):11981-11990.
5. Kopp RE, Kirschvink JL, Hilburn IA, Nash CZ (2005) The Paleoproterozoic snowball Earth: A climate disaster triggered by the evolution of oxygenic photosynthesis. Proc Natl Acad Sci USA 102(32):11131-11136.
6. Zahnle KJ, Claire M, Catling D (2006) The loss of mass-independent fractionation in sulfur due to a Palaeoproterozoic collapse of atmospheric methane. Geobiology 4(4):271-283.
7. Konhauser KO, et al. (2009) Oceanic nickel depletion and a methanogen famine before the Great Oxidation Event. Nature 458(7239):750-753.
8. Catling DC, Zahnle KJ, McKay CP (2002) What caused the second rise of O2 in the Late Proterozoic? Methane, sulfate, and irreversible oxidation. Astrobiology 2(4):5-9.
9. Pavlov AA, Hurtgen MT, Kasting JF, Arthur MA (2003) Methane-rich Proterozoic atmosphere? Geology 31(1):87-90.
10. Roberson AL, Roadt J, Halevy I, Kasting JF (2011) Greenhouse warming by nitrous oxide and methane in the Proterozoic Eon. Geobiology 9(4):313-320.
11. Shen B, et al. (2016) Molar tooth carbonates and benthic methane fluxes in Proterozoic oceans. Nat Commun 7:1-317.
12. Bjerrum CJ, Canfield DE (2011) Towards a quantitative understanding of the late Neoproterozoic carbon cycle. Proc Natl Acad Sci USA 108(14):5542-5547.
13. Daines SJ, Lenton TM (2016) The effect of widespread early aerobic marine ecosystems on methane cycling and the Great Oxidation. Earth Planet Sci Lett 434:42-51.
14. Lovley DR, Klug MJ (1983) Sulfate reducers can outcompete methanogens at freshwater sulfate concentrations. Appl Environ Microbiol 45(1):187-192.
15. Boetius A, et al. (2000) A marine microbial consortium apparently mediating anaerobic oxidation of methane. Nature 407(6804):623-626.
16. Claire MW, Catling DC, Zahnle KJ (2006) Biogeochemical modelling of the rise in atmospheric oxygen. Geobiology 4(4):239-269.
17. Goldblatt C, Lenton TM, Watson AJ (2006) Bistability of atmospheric oxygen and the Great Oxidation. Nature 443(7112):683-686.
18. Berner RA (1989) Biogeochemical cycles of carbon and sulfur and their effect on atmospheric oxygen over Phanerozoic time. Palaeogeogr Palaeoclimatol Palaeoecol 75(1-2):97-122.
19. Berner RA, Petsch ST (1998) The sulfur cycle and atmospheric oxygen. Science 282:1426-1427.
20. Reeburgh WS (2007) Oceanic methane biogeochemistry. Chem Rev 107(2):486-513.
21. Kah LC, Lyons TW, Frank TD (2004) Low marine sulphate and protracted oxygenation of the Proterozoic biosphere. Nature 431(7010):834-838.
22. Scott C, et al. (2014) Pyrite multiple-sulfur isotope evidence for rapid expansion and contraction of the early Paleoproterozoic seawater sulfate reservoir. Earth Planet Sci Lett 389:95-104.
23. Beal EJ, Claire MW, House CH (2011) High rates of anaerobic methanotrophy at low sulfate concentrations with implications for past and present methane levels. Geobiology 9(2):131-139.
24. Crowe SA, et al. (2011) The methane cycle in ferruginous Lake Matano. Geobiology 9(1):61-78.
25. Riedinger N, et al. (2014) An inorganic geochemical argument for coupled anaerobic oxidation of methane and iron reduction in marine sediments. Geobiology 12(2):172-181.
26. Beal EJ, House CH, Orphan VJ (2009) Manganese- and iron-dependent marine methane oxidation. Science 325(5937):184-187.
27. Catling DC, Claire MW, Zahnle KJ (2007) Anaerobic methanotrophy and the rise of atmospheric oxygen. Philos Trans A Math Phys Eng Sci 365(1856):1867-1888.
28. Lyons TW, Reinhard CT, Planavsky NJ (2014) The rise of oxygen in Earth's early ocean and atmosphere. Nature 506(7488):307-315.
29. Planavsky NJ, et al. (2014) Low mid-Proterozoic atmospheric oxygen levels and the delayed rise of animals. Science 346(6209):635-638.
30. Ridgwell A, et al. (2007) Marine geochemical data assimilation in an efficient Earth System Model of global biogeochemical cycling. Biogeosciences 4(1):87-104.
31. Edwards NR, Marsh R (2005) Uncertainties due to transport-parameter sensitivity in an efficient 3-D ocean-climate model. Clim Dyn 24(4):415-433.
32. Olson SL, Kump LR, Kasting JF (2013) Quantifying the areal extent and dissolved oxygen concentrations of Archean oxygen oases. Chem Geol 362:35-43.
33. Reeburgh WS, et al. (1991) Black Sea methane geochemistry. Deep Sea Res A 38(Suppl 2A):S1189-S1210.
34. Pavlov AA, Kasting JF (2002) Mass-independent fractionation of sulfur isotopes in Archean sediments: Strong evidence for an anoxic Archean atmosphere. Astrobiology 2(1):27-41.
35. Sheldon ND (2013) Causes and consequences of low atmospheric pCO2 in the Late Mesoproterozoic. Chem Geol 362:224-231.
36. Buick R (2007) Did the Proterozoic 'Canfield Ocean' cause a laughing gas greenhouse? Geobiology 5(2):97-100.
37. Haqq-Misra JD, Domagal-Goldman SD, Kasting PJ, Kasting JF (2008) A revised, hazy methane greenhouse for the Archean Earth. Astrobiology 8(6):1127-1137.
38. Pogge von Strandmann PA, et al. (2015) Selenium isotope evidence for progressive oxidation of the Neoproterozoic biosphere. Nat Commun 6:1-157.
39. Johnston DT, et al. (2013) Searching for an oxygenation event in the fossiliferous Ediacaran of northwestern Canada. Chem Geol 362:273-286.
40. Kendall B, et al. (2015) Uranium and molybdenum isotope evidence for an episode of widespread ocean oxygenation during the late Ediacaran Period. Geochim Cosmochim Acta 156:173-193.
41. Sperling EA, et al. (2015) Statistical analysis of iron geochemical data suggests limited late Proterozoic oxygenation. Nature 523(7561):451-454.
42. Schrag DP, Berner RA, Hoffman PF, Halverson GP (2002) On the initiation of a snowball Earth. Geochem Geophys Geosyst 3(6):1-24.
43. Meyer KM, Kump LR, Ridgwell A (2008) Biogeochemical controls on photic-zone euxinia during the end-Permian mass extinction. Geology 36(9):747-750.
44. Pallud C, Van Cappellen P (2006) Kinetics of microbial sulfate reduction in estuarine sediments. Geochim Cosmochim Acta 70(5):1148-1162.
45. Wegener G, Boetius A (2009) An experimental study on short-term changes in the anaerobic oxidation of methane in response to varying methane and sulfate fluxes. Biogeosciences 6(5):867-876.
46. Regnier P, et al. (2011) Quantitative analysis of anaerobic oxidation of methane (AOM) in marine sediments: A modeling perspective. Earth Sci Rev 106(1):105-130.
47. Wanninkhof R (1992) Relationship between wind speed and gas exchange over the ocean. J Geophys Res Oceans 97(C5):7373-7382.
48. Planavsky NJ, et al. (2010) The evolution of the marine phosphate reservoir. Nature 467(7319):1088-1090.
49. Ward B, Kilpatrick K, Novelli P, Scranton M (1987) Methane oxidation and methane fluxes in the ocean surface layer and deep anoxic waters. Nature 327(6119):226-229.
50. Etiope G, Sherwood Lollar B (2013) Abiotic methane on Earth. Rev Geophys 51(2):276-299.