{"id":115821,"date":"2025-08-28T08:28:10","date_gmt":"2025-08-28T08:28:10","guid":{"rendered":"https:\/\/www.newsbeep.com\/us\/115821\/"},"modified":"2025-08-28T08:28:10","modified_gmt":"2025-08-28T08:28:10","slug":"two-billion-year-transitional-oxygenation-of-the-earths-surface","status":"publish","type":"post","link":"https:\/\/www.newsbeep.com\/us\/115821\/","title":{"rendered":"Two-billion-year transitional oxygenation of the Earth\u2019s surface"},"content":{"rendered":"

Lyons, T. W. et al. Co\u2010evolution of early Earth environments and microbial life. Nat. Rev. Microbiol. 22, 572\u2013586 (2024).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Kump, L. R. The rise of atmospheric oxygen. Nature 451, 277\u2013278 (2008).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Holland, H. D. The oxygenation of the atmosphere and oceans. Phil. Trans. R. Soc. B 361, 903\u2013915 (2006).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Kasting, J. F. Earth\u2019s early atmosphere. Science 259, 920\u2013926 (1993).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Des Marais, D. J., Strauss, H., Summons, R. E. & Hayes, J. M. Carbon isotope evidence for the stepwise oxidation of the Proterozoic environment. Nature 359, 605\u2013609 (1992).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Och, L. M. & Shields-Zhou, G. A. The Neoproterozoic oxygenation event: environmental perturbations and biogeochemical cycling. Earth Sci. Rev. 110, 26\u201357 (2012).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Krause, A. J. et al. Stepwise oxygenation of the Paleozoic atmosphere. Nat. Commun. 9, 4081 (2018).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Wallace, M. W. et al. Oxygenation history of the Neoproterozoic to early Phanerozoic and the rise of land plants. Earth Planet. Sci. Lett. 466, 12\u201319 (2017).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Lu, W. et al. Late inception of a resiliently oxygenated upper ocean. Science 5372, eaar5372 (2018).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Liu, X.-M. et al. Tracing Earth\u2019s O2 evolution using Zn\/Fe ratios in marine carbonates. Geochem. Perspect. Lett. 2, 24\u201334 (2016).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Pogge Von Strandmann, P. A. E. et al. Selenium isotope evidence for progressive oxidation of the Neoproterozoic biosphere. Nat. Commun. 6, 10157 (2015).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Dahl, T. W. et al. Devonian rise in atmospheric oxygen correlated to the radiations of terrestrial plants and large predatory fish. Proc. Natl Acad. Sci. USA 107, 17911\u201317915 (2010).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Stolper, D. A. & Keller, C. B. A record of deep-ocean dissolved O2 from the oxidation state of iron in submarine basalts. Nature 553, 323\u2013327 (2018).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Stockey, R. G. et al. Sustained increases in atmospheric oxygen and marine productivity in the Neoproterozoic and Palaeozoic eras. Nat. Geosci. 17, 667\u2013674 (2024).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Krause, A. J., Mills, B. J. W. W., Merdith, A. S., Lenton, T. M. & Poulton, S. W. Extreme variability in atmospheric oxygen levels in the late Precambrian. Sci. Adv. 8, eabm8191 (2022).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Cole, D. B. et al. A shale-hosted Cr isotope record of low atmospheric oxygen during the Proterozoic. Geology 44, 555\u2013558 (2016).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Bao, H. Sulfate: a time capsule for Earth\u2019s O2, O3, and H2O. Chem. Geol. 395, 108\u2013118 (2015).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Planavsky, N. J., Reinhard, C. T., Isson, T. T., Ozaki, K. & Crockford, P. W. Large mass-independent oxygen isotope fractionations in mid-Proterozoic sediments: evidence for a low-oxygen atmosphere? Astrobiology 20, 628\u2013636 (2020).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Cao, X. & Bao, H. Dynamic model constraints on oxygen-17 depletion in atmospheric O2 after a snowball Earth. Proc. Natl Acad. Sci. USA 110, 14546\u201314550 (2013).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Poulton, S. W. et al. A 200-million-year delay in permanent atmospheric oxygenation. Nature 592, 232\u2013236 (2021).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Farquhar, J., Bao, H. & Thiemens, M. Atmospheric influence of Earth\u2019s earliest sulfur cycle. Science 289, 756\u2013758 (2000).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Uveges, B. T., Izon, G., Ono, S., Beukes, N. J. & Summons, R. E. Reconciling discrepant minor sulfur isotope records of the Great Oxidation Event. Nat. Commun. 14, 1\u201312 (2023).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Mitchell, R. N., Feng, L., Zhang, Z. & Peng, P. Carbonate-organic decoupling during the first Neoproterozoic carbon isotope excursion. Innov. Geosci. 1, 100046 (2023).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Rothman, D. H., Hayes, J. M. & Summons, R. E. Dynamics of the Neoproterozoic carbon cycle. Proc. Natl Acad. Sci. USA 100, 8124\u20138129 (2003).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Knoll, A. H. & Nowak, M. A. The timetable of evolution. Sci. Adv. 3, e1603076 (2017).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Ye, Q. et al. The survival of benthic macroscopic phototrophs on a Neoproterozoic snowball Earth. Geology 43, 507\u2013510 (2015).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Darroch, S. A. F., Smith, E. F., Laflamme, M. & Erwin, D. H. Ediacaran extinction and Cambrian explosion. Trends Ecol. Evol. 33, 653\u2013663 (2018).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Catling, D. C. & Zahnle, K. J. The Archean atmosphere. Sci. Adv. 6, eaax1420 (2020).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Turner, E. C. & Bekker, A. Thick sulfate evaporite accumulations marking a mid-Neoproterozoic oxygenation event (Ten Stone Formation, Northwest Territories, Canada). Geol. Soc. Am Bull. 128, B31268.1 (2015).<\/p>\n

Reinhard, C. T. & Planavsky, N. J. The history of ocean oxygenation. Ann. Rev. Mar. Sci. 14, 331\u2013353 (2022).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Wang, H. et al. A benthic oxygen oasis in the early Neoproterozoic ocean. Precambrian Res. 355, 106085 (2021).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Wang, H. et al. Spatiotemporal redox heterogeneity and transient marine shelf oxygenation in the Mesoproterozoic ocean. Geochim. Cosmochim. Acta 270, 201\u2013217 (2020).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Kohl, I. & Bao, H. Triple-oxygen-isotope determination of molecular oxygen incorporation in sulfate produced during abiotic pyrite oxidation (pH=2\u201311). Geochim. Cosmochim. Acta 75, 1785\u20131798 (2011).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Balci, N., Shanks, W. C., Mayer, B. & Mandernack, K. W. Oxygen and sulfur isotope systematics of sulfate produced by bacterial and abiotic oxidation of pyrite. Geochim. Cosmochim. Acta 71, 3796\u20133811 (2007).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Killingsworth, B. A. et al. Towards a holistic sulfate\u2013water\u2013O2 triple oxygen isotope systematics. Chem. Geol. 588, 120678 (2022).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Crockford, P. W. et al. Depositional controls on \u0394\u203217O signatures of sedimentary sulfate. Geophys. Res. Lett. 52, e2024GL114184 (2025).<\/p>\n

Hodgskiss, M. S. W., Crockford, P. W., Peng, Y., Wing, B. A. & Horner, T. J. A productivity collapse to end Earth\u2019s great oxidation. Proc. Natl Acad. Sci. USA 116, 17207\u201317212 (2019).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Wang, H. et al. Sulfate triple-oxygen-isotope evidence confirming oceanic oxygenation 570 million years ago. Nat. Commun. 14, 4315 (2023).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Peng, Y., Hattori, S., Zuo, P., Ma, H. & Bao, H. Record of pre-industrial atmospheric sulfate in continental interiors. Nat. Geosci. 16, 619\u2013624 (2023).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Crockford, P. W. et al. Claypool continued: extending the isotopic record of sedimentary sulfate. Chem. Geol. 513, 200\u2013225 (2019).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Bao, H., Lyons, J. R. & Zhou, C. Triple oxygen isotope evidence for elevated CO2 levels after a Neoproterozoic glaciation. Nature 453, 504\u2013506 (2008).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Waldeck, A. R. et al. Marine sulphate captures a Paleozoic transition to a modern terrestrial weathering environment. Nat. Commun. 16, 2087 (2025).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Liu, P. et al. Triple oxygen isotope constraints on atmospheric O2 and biological productivity during the mid-Proterozoic. Proc. Natl Acad. Sci. USA 118, e2105074118 (2021).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Wostbrock, J. A. G., Cano, E. J. & Sharp, Z. D. An internally consistent triple oxygen isotope calibration of standards for silicates, carbonates and air relative to VSMOW2 and SLAP2. Chem. Geol. 533, 119432 (2020).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Scott, A. C. & Glasspool, I. J. The diversification of Paleozoic fire systems and fluctuations in atmospheric oxygen concentration. Proc. Natl Acad. Sci. USA 103, 10861\u201310865 (2006).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Reinhard, C. T., Planavsky, N. J. & Lyons, T. W. Long-term sedimentary recycling of rare sulphur isotope anomalies. Nature 497, 100\u2013103 (2013).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Evans, S. D., Diamond, C. W., Droser, M. L. & Lyons, T. W. Dynamic oxygen and coupled biological and ecological innovation during the second wave of the Ediacara Biota. Emerg. Top. Life Sci. 2, 223\u2013233 (2018).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Derry, L. A. A burial diagenesis origin for the Ediacaran Shuram\u2013Wonoka carbon isotope anomaly. Earth Planet. Sci. Lett. 294, 152\u2013162 (2010).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Schrag, D. P., Higgins, J. A., Macdonald, F. A. & Johnston, D. T. Authigenic carbonate and the history of the global carbon cycle. Science 339, 540\u2013543 (2013).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Cramer, B. D. & Jarvis, I. in Geologic Time Scale 2020 (eds Gradstein, F. M. et al.) 309\u2013343 (Elsevier, 2020).<\/p>\n

Peng, Y. et al. Widespread contamination of carbonate-associated sulfate by present-day secondary atmospheric sulfate: evidence from triple oxygen isotopes. Geology 42, 815\u2013818 (2014).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Bao, H. Purifying barite for oxygen isotope measurement by dissolution and reprecipitation in a chelating solution. Anal. Chem. 78, 304\u2013309 (2006).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Wei, Y., Yan, H., Peng, Y. & Bao, H. Quantitative conversion of sulfate oxygen for high-precision triple oxygen isotope analysis. Anal. Chem. 96, 19387\u201319395 (2024).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Cao, X. & Bao, H. Small triple oxygen isotope variations in sulfate: mechanisms and applications. Rev. Mineral. Geochem. 86, 463\u2013488 (2021).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Canfield, D. E., Knoll, A. H., Poulton, S. W., Narbonne, G. M. & Dunning, G. R. Carbon isotopes in clastic rocks and the Neoproterozoic carbon cycle. Am. J. Sci. 320, 97\u2013124 (2020).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Zhang, Z. et al. Oldest-known Neoproterozoic carbon isotope excursion: earlier onset of Neoproterozoic carbon cycle volatility. Gondwana Res. 94, 1\u201311 (2021).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Halverson, G. P., Porter, S. M. & Shields, G. A. In Geologic Time Scale 2020 (eds Gradstein, F. M. et al.) 495\u2013519 (Elsevier, 2020).<\/p>\n

Kendall, B., Creaser, R. A. & Selby, D. Re\u2013Os geochronology of postglacial black shales in Australia: constraints on the timing of \u2018Sturtian\u2019 glaciation. Geology 34, 729\u2013732 (2006).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Condon, D. et al. U\u2013Pb ages from the Neoproterozoic Doushantuo Formation, China. Science 308, 95\u201398 (2005).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Lu, M. et al. The DOUNCE event at the top of the Ediacaran Doushantuo Formation, South China: broad stratigraphic occurrence and non-diagenetic origin. Precambrian Res. 225, 86\u2013109 (2013).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Fan, R., Deng, S. H. & Zhang, X. L. Significant carbon isotope excursions in the Cambrian and their implications for global correlations. Sci. China Earth Sci. 54, 1686\u20131695 (2011).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Wen, J. & Thiemens, M. H. Multi\u2010isotope study of the O(1D) + CO2 exchange and stratospheric consequences. J. Geophys. Res. Atmos. 98, 12801\u201312808 (1993).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Burke, A. et al. Sulfur isotopes in rivers: Insights into global weathering budgets, pyrite oxidation, and the modern sulfur cycle. Earth Planet. Sci. Lett. 496, 168\u2013177 (2018).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Heidel, C. & Tichomirowa, M. The role of dissolved molecular oxygen in abiotic pyrite oxidation under acid pH conditions\u2014experiments with 18O-enriched molecular oxygen. Appl. Geochem. 25, 1664\u20131675 (2010).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Sahoo, S. K. et al. Oceanic oxygenation events in the anoxic Ediacaran ocean. Geobiology 14, 457\u2013468 (2016).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Bao, H., Cao, X. & Hayles, J. A. Triple oxygen isotopes: fundamental relationships and applications. Annu. Rev. Earth Planet Sci. 44, 463\u2013492 (2016).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Planavsky, N. J. et al. A sedimentary record of the evolution of the global marine phosphorus cycle. Geobiology 21, 168\u2013174 (2022).<\/p>\n


\n Google Scholar<\/a>\u00a0\n <\/p>\n

Shi, W. et al. Sulfur isotope evidence for transient marine-shelf oxidation during the Ediacaran Shuram Excursion. Geology 46, 267\u2013270 (2018).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

Fike, D. A., Grotzinger, J. P., Pratt, L. M. & Summons, R. E. Oxidation of the Ediacaran Ocean. Nature 444, 744\u2013747 (2006).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n

McFadden, K. A. et al. Pulsed oxidation and biological evolution in the Ediacaran Doushantuo Formation. Proc. Natl Acad. Sci. USA 105, 3197\u20133202 (2008).<\/p>\n

ADS<\/a>\u00a0
\n
\n Google Scholar<\/a>\u00a0\n <\/p>\n","protected":false},"excerpt":{"rendered":"Lyons, T. W. et al. Co\u2010evolution of early Earth environments and microbial life. Nat. Rev. Microbiol. 22, 572\u2013586…\n","protected":false},"author":2,"featured_media":115822,"comment_status":"","ping_status":"","sticky":false,"template":"","format":"standard","meta":{"footnotes":""},"categories":[32],"tags":[75208,24382,74989,63262,1159,75209,1160,79],"class_list":{"0":"post-115821","1":"post","2":"type-post","3":"status-publish","4":"format-standard","5":"has-post-thumbnail","7":"category-science","8":"tag-atmospheric-chemistry","9":"tag-carbon-cycle","10":"tag-element-cycles","11":"tag-geochemistry","12":"tag-humanities-and-social-sciences","13":"tag-marine-chemistry","14":"tag-multidisciplinary","15":"tag-science"},"_links":{"self":[{"href":"https:\/\/www.newsbeep.com\/us\/wp-json\/wp\/v2\/posts\/115821","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/www.newsbeep.com\/us\/wp-json\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/www.newsbeep.com\/us\/wp-json\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/www.newsbeep.com\/us\/wp-json\/wp\/v2\/users\/2"}],"replies":[{"embeddable":true,"href":"https:\/\/www.newsbeep.com\/us\/wp-json\/wp\/v2\/comments?post=115821"}],"version-history":[{"count":0,"href":"https:\/\/www.newsbeep.com\/us\/wp-json\/wp\/v2\/posts\/115821\/revisions"}],"wp:featuredmedia":[{"embeddable":true,"href":"https:\/\/www.newsbeep.com\/us\/wp-json\/wp\/v2\/media\/115822"}],"wp:attachment":[{"href":"https:\/\/www.newsbeep.com\/us\/wp-json\/wp\/v2\/media?parent=115821"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/www.newsbeep.com\/us\/wp-json\/wp\/v2\/categories?post=115821"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/www.newsbeep.com\/us\/wp-json\/wp\/v2\/tags?post=115821"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}