DOCSLIB.ORG

Late Proterozoic Transitions in Climate, Oxygen, and Tectonics, and the Rise of Complex Life

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Late Proterozoic Transitions in Climate, Oxygen, and Tectonics, and the Rise of Complex Life LATE PROTEROZOIC TRANSITIONS IN CLIMATE, OXYGEN, AND TECTONICS, AND THE RISE OF COMPLEX LIFE NOAH J. PLANAVSKY1, LIDYA G. TARHAN1, ERIC J. BELLEFROID1, DAVID A. D. EVANS1, CHRISTOPHER T. REINHARD2, GORDON D. LOVE3, AND TIMOTHY W. LYONS3 1Department of Geology and Geophysics, Yale University, New Haven, CT 06520, USA <[email protected]> 2School of Earth and Atmospheric Sciences, Georgia Institute of Technology, Atlanta, GA 30332, USA 3Department of Earth Sciences, University of California-Riverside, Riverside, CA 92521, USA ABSTRACT.—The transition to the diverse and complex biosphere of the Ediacaran and early Paleozoic is the culmination of a complex history of tectonic, climate, and geochemical development. Although much of this rise occurred in the middle and late intervals of the Neoproterozoic Era (1000–541 million years ago [Ma]), the foundation for many of these developments was laid much earlier, during the latest Mesoproterozic Stenian Period (1200–1000 Ma) and early Neoproterozoic Tonian Period (1000–720 Ma). Concurrent with the development of complex ecosystems, changes in continental configuration and composition, and plate tectonic interaction have been proposed as major shapers of both climate and biogeochemical cycling, but there is little support in the geologic record for overriding tectonic controls. Biogeochemical evidence, however, suggests that an expansion of marine oxygen concentrations may have stabilized nutrient cycles and created more stable environmental conditions under which complex, eukaryotic life could gain a foothold and flourish. The interaction of tectonic, biogeochemical, and climate processes, as described in this paper, resulted in the establishment of habitable environments that fostered the Ediacaran and early Phanerozoic radiations of animal life and the emergence of complex, modern-style ecosystems. INTRODUCTION diversification of eukaryotes, the earliest evidence for metazoan life, and dramatic reorganization of surface-ocean and benthic ecosystems and The late Proterozoic was witness to perhaps the environments. As such, this period likely provides most profound biological and geochemical an early glimpse of the regulatory feedbacks that, transition in Earth’s history. In contrast, the in the modern ocean, control the interactions preceding billion years appear to be characterized among organisms and biogeochemical cycling in by biogeochemical, climatic, and evolutionary Earth’s surface environments. Recent work also stasis. For example, there is little to no evidence suggests that this interval corresponded to a shift for continental ice sheets of any kind during this in the marine redox landscape, as well as surface- time interval (flippantly termed the “boring ocean oxygen levels (Lyons et al., 2014; Thomson billion”), suggesting climatic stability, and et al., 2014). Conventionally, Neoproterozoic unusually invariant carbon isotope data attest to oxygenation is considered to be a unidirectional the stability of the global carbon cycle. The late process, but it is likely that the Neoproterozoic, Proterozoic, in contrast, was characterized by and potentially even the early Paleozoic, were extreme biogeochemical and climatic volatility, as characterized by dynamic swings in oxygen recorded by pronounced and rapid variability in levels. the carbon isotope record and the stratigraphic The emerging view is that there are three record of repeated low-latitude glaciations of concurrent, but likely not coincidental, unparalleled scale and severity (Canfield, 2005; phenomena characterizing the early Lyons et al., 2012; Knoll, 2014). Moreover, the Neoproterozoic Earth system: 1) a shift in late Proterozoic records the evolution and ecosystem structure and function within the In: Earth-Life Transitions: Paleobiology in the Context of Earth System Evolution. The Paleontological Society Papers, Volume 21, P. David Polly, Jason J. Head, and David L. Fox (eds.). The Paleontological Society Short Course, October 31, 2015. Copyright © 2015 The Paleontological Society. PLANAVSKY ET AL.: LATE PROTEROZOIC RISE OF COMPLEX LIFE ocean, including the rise of eukaryotic algal the operation of eukaryote-driven processes. primary producers and the eventual emergence of Eukaryotic behavior, ranging from metazoan life; 2) severe low-latitude glaciation phytoplanktonic carbon fixation to filter-feeding, (the so-called ‘Snowball Earth’ events) and carnivory, bioturbation, and reef-building at carbon cycle instability; and 3) further and diverse scales and trophic levels, influences potentially dramatic oxygenation of Earth’s habitability and colonization. These relationships surface. The goal of this paper is to review the also shape sedimentological processes and timing and mechanistic relationships among these regulate biogeochemical cycling. In so doing, phenomena and to discuss our view of the eukaryotes mold the physical, chemical, and development and interaction of these factors may biotic landscape of both the benthos and the have shaped Earth’s environments and biosphere. surface ocean. As such, their appearance and We also hope to elucidate the role—if any—that radiation, which shifted the world’s oceans from a tectonic forcing may have played in controlling prokaryotic to eukaryotic mode, likely had a the observed Neoproterozoic biogeochemical concomitantly substantial impact upon transitions. An unusual concentration of environments as well as biogeochemical and continental area in the tropics is generally biotic processes (Fig. 1). Reconstructing the accepted to have been a key factor in the timing and nature of this transition, however, has development of extensive, ‘Snowball’-scale been limited by the ability to constrain the first glaciation. For example, a preponderance of appearance of the earliest eukaryotes and to track continental landmass at low latitudes would have their subsequent diversification—a task allowed for continued chemical weathering of the complicated by the likelihood that early continents, and thus extended carbon dioxide eukaryotic life was small, single-celled, and soft- drawdown, as the ice sheets advanced toward bodied. Efforts to reconstruct the early eukaryote lower latitudes. However, it is unclear if this record have been hampered by issues of both configuration was unique to the early preservation and recognition (Knoll, 2014). Neoproterozoic relative to the preceding billion However, recent efforts at improved sample years, and thus may have been only one of several collection, fossil detection and imaging, controlling factors. Finally, shifts in the flux of assessments of syngeity, and reconstruction of volcanogenic carbon dioxide or variations in the micro- and macro-scale taphonomic processes composition of the upper continental crust may (e.g., Javaux et al., 2004; Grey and Calver, 2007; have also been key contributing factors to the Anderson et al., 2014) are beginning to fill the climatic shifts recorded in the stratigraphic record gaps in the fossil record. The encouraging result is (Godderis et al., 2003; McKenzie et al., 2014), a clearer picture of early Earth ecosystems at the and further exploration of these ideas is essential dawn of eukaryotic life. in order to reconstruct the mechanisms that Historically, molecular-clock estimates for the regulated the biological, chemical, and physical origin of eukaryotes range widely from the dynamics of the Neoproterozoic world. Archean to the Paleoproterozoic, This paper reviews current records of late Mesoproterozoic, or even the Neoproterozoic Paleoproterozoic to early Neoproterozoic (1.8 Ga (e.g., Cavalier-Smith, 2002; Douzery et al., 2004; to 0.7 Ga) paleobiological diversity and Hedges et al., 2004; Yoon et al., 2004). The paleoecological complexity, marine redox molecular (biomarker) record of fossil lipids can, regimes, paleoclimate, atmospheric oxygen levels, in certain cases, fingerprint eukaryotes or even paleogeography, and crustal composition. We then particular eukaryotic clades. However, Archean explore relationships between these records and and Proterozoic biomarker data are susceptible to several Earth-system models that link climate, artifacts due to issues of high maturity and tectonics, and geochemical cycling to the initial contamination, and these factors need to be radiation of eukaryotes and complex ecosystems. assessed carefully. Rigorous self-consistency checks are needed to verify syngeneity of any THE RISE OF EUKARYOTES: THE organic compounds detected; thus, biomarker PROTEROZOIC FOSSIL RECORD evidence for eukaryotes other than from the youngest intervals of the Proterozoic has largely The composition, complexity, and distribution of been equivocal (e.g., Blumenberg et al., 2012; modern marine ecosystems are engineered Pawlowska et al., 2013; French et al., 2015). dramatically by the presence of eukaryotes and Efforts to differentiate early, single-celled 2 THE PALEONTOLOGICAL SOCIETY PAPERS, V. 21 FIGURE 1.—Approximate dates for the first appearance of various eukaryotic groups in the body fossil record (open black circles), the molecular fossil record (open blue circle), and best estimates from molecular clock techniques for the emergence of major crown groups (open red circles). Also shown are the fossils appearances of large ornamented Ediacaran microfossils (LOEMs) and vase shaped microfossils (VSMs). The vertical gray field denotes an interval of major eukaryotic diversification. After Planavsky et al. (2014). eukaryotes from prokaryotes in the body-fossil the evolutionary
Load more

Recommended publications
  • Reconciling Proxy Records and Models of Earth's Oxygenation During the Neoproterozoic and Palaeozoic
    This is a repository copy of Reconciling proxy records and models of Earth's oxygenation during the Neoproterozoic and Palaeozoic. White Rose Research Online URL for this paper: http://eprints.whiterose.ac.uk/165529/ Version: Accepted Version Article: Tostevin, R and Mills, BJW orcid.org/0000-0002-9141-0931 (2020) Reconciling proxy records and models of Earth's oxygenation during the Neoproterozoic and Palaeozoic. Interface Focus, 10 (4). 20190137. ISSN 2042-8901 https://doi.org/10.1098/rsfs.2019.0137 © 2020 The Author(s). This is an author produced version of an article published in Interface Focus. Uploaded in accordance with the publisher's self-archiving policy. Reuse Items deposited in White Rose Research Online are protected by copyright, with all rights reserved unless indicated otherwise. They may be downloaded and/or printed for private study, or other acts as permitted by national copyright laws. The publisher or other rights holders may allow further reproduction and re-use of the full text version. This is indicated by the licence information on the White Rose Research Online record for the item. Takedown If you consider content in White Rose Research Online to be in breach of UK law, please notify us by emailing [email protected] including the URL of the record and the reason for the withdrawal request. [email protected] https://eprints.whiterose.ac.uk/ 1 Reconciling proxy records and models of E oxygenation during 2 the Neoproterozoic and Palaeozoic 3 Rosalie Tostevin1 and Benjamin J. W. Mills2 4 1Department of Geological Sciences, University of Cape Town, Rondebosch, Cape Town, 5 South Africa.
    [Show full text]
  • The Huronian Glaciation
    Brasier, A.T., Martin, A.P., Melezhik, V.A., Prave, A.R., Condon, D.J., and Fallick, A.E. (2013) Earth's earliest global glaciation? Carbonate geochemistry and geochronology of the Polisarka Sedimentary Formation, Kola Peninsula, Russia. Precambrian Research, 235 . pp. 278-294. ISSN 0301-9268 Copyright © 2013 Elsevier B.V. A copy can be downloaded for personal non-commercial research or study, without prior permission or charge Content must not be changed in any way or reproduced in any format or medium without the formal permission of the copyright holder(s) When referring to this work, full bibliographic details must be given http://eprints.gla.ac.uk/84700 Deposited on: 29 August 2013 Enlighten – Research publications by members of the University of Glasgow http://eprints.gla.ac.uk 1 Earth’s earliest global glaciation? Carbonate geochemistry and geochronology of the 2 Polisarka Sedimentary Formation, Kola Peninsula, Russia 3 4 A.T. Brasier1,6*, A.P. Martin2+, V.A. Melezhik3,4, A.R. Prave5, D.J. Condon2, A.E. Fallick6 and 5 FAR-DEEP Scientists 6 7 1 Faculty of Earth and Life Sciences, Vrije Universiteit Amsterdam, De Boelelaan 1085, 1081HV 8 Amsterdam 9 2 NERC Isotope Geosciences Laboratory, British Geological Survey, Environmental Science 10 Centre, Keyworth, UK. NG12 5GG 11 3 Geological Survey of Norway, Postboks 6315 Slupen, NO-7491 Trondheim, Norway 12 4 Centre for Geobiology, University of Bergen, Postboks 7803, NO-5020 Bergen, Norway 13 5 Department of Earth and Environmental Sciences, University of St Andrews, St Andrews KY16 14 9AL, Scotland, UK 15 6 Scottish Universities Environmental Research Centre, Rankine Avenue, East Kilbride, Scotland.
    [Show full text]
  • Early Atmosphere and Hydrosphere Oxygenation: Clues from Precambrian Paleosols and Chemical Sedimentary Records of India
    Article 175 by Partha Pratim Chakraborty1, Joydip Mukhopadhyay2, Pritam P. Paul3, Dhiraj Mohan Banerjee1 and Melinda K. Bera4 Early atmosphere and hydrosphere oxygenation: Clues from Precambrian paleosols and chemical sedimentary records of India 1. Department of Geology, University of Delhi, Delhi-11007 2. Department of Geology, Presidency University, Kolkata- 700073 3. Department of Earth Sciences, Indian Institute of Technology, Mumbai- 400076 4. Manav Rachna University, Faridabad, Haryana, India - 121004 Corresponding author E-mail: [email protected] (Received : 23/02/2019; Revised accepted : 13/11/2019) https://doi.org/10.18814/epiiugs/2020/020011 A number of Precambrian sedimentary basins of the (Hoffman et al., 1998), biological evolution leading to the advent of Indian subcontinent offer scope for tracking early multicellular life (Knoll, 1994) and major changes in the upper crustal composition (Taylor and McLennan, 1997). None of these changes oxygenation history of atmosphere and hydrosphere. followed uniform and steady character e.g., Paleoproterozoic (2500 - Available studies, though certainly not exhaustive, record 1800 Ma) and late Neoproterozoic (800 -541 Ma) witnessed major signatures of pre-great oxygenation event (GOE) whiffs biological, tectonic, climatic and atmospheric changes. The billion of atmospheric oxygenation between 3.29 and 3.02 Ga. year interval (1800 - 800 Ma) mostly encompassing the Besides, available geochemical signatures from Mesoproterozoic time on the other hand is marked by tectonic, climatic and evolutionary stability (Reddy and Evans, 2009; Mukherjee et Precambrian sedimentary rocks (BIF, sulfides, sulfates, al., 2018). Nevertheless, amongst above mentioned breakthrough argillaceous sediments and phosphorites) suggest a changes, the most debated one is oxygenation of Proterozoic generally sub-oxic shallow marine and bipartite oxic- atmosphere and hydrosphere, since it is intimately tied up with sulfidic condition in late Paleoproterozoic and appearance and proliferation of life.
    [Show full text]
  • Timeline of Natural History
    Timeline of natural history This timeline of natural history summarizes significant geological and Life timeline Ice Ages biological events from the formation of the 0 — Primates Quater nary Flowers ←Earliest apes Earth to the arrival of modern humans. P Birds h Mammals – Plants Dinosaurs Times are listed in millions of years, or Karo o a n ← Andean Tetrapoda megaanni (Ma). -50 0 — e Arthropods Molluscs r ←Cambrian explosion o ← Cryoge nian Ediacara biota – z ←Earliest animals o ←Earliest plants i Multicellular -1000 — c Contents life ←Sexual reproduction Dating of the Geologic record – P r The earliest Solar System -1500 — o t Precambrian Supereon – e r Eukaryotes Hadean Eon o -2000 — z o Archean Eon i Huron ian – c Eoarchean Era ←Oxygen crisis Paleoarchean Era -2500 — ←Atmospheric oxygen Mesoarchean Era – Photosynthesis Neoarchean Era Pong ola Proterozoic Eon -3000 — A r Paleoproterozoic Era c – h Siderian Period e a Rhyacian Period -3500 — n ←Earliest oxygen Orosirian Period Single-celled – life Statherian Period -4000 — ←Earliest life Mesoproterozoic Era H Calymmian Period a water – d e Ectasian Period a ←Earliest water Stenian Period -4500 — n ←Earth (−4540) (million years ago) Clickable Neoproterozoic Era ( Tonian Period Cryogenian Period Ediacaran Period Phanerozoic Eon Paleozoic Era Cambrian Period Ordovician Period Silurian Period Devonian Period Carboniferous Period Permian Period Mesozoic Era Triassic Period Jurassic Period Cretaceous Period Cenozoic Era Paleogene Period Neogene Period Quaternary Period Etymology of period names References See also External links Dating of the Geologic record The Geologic record is the strata (layers) of rock in the planet's crust and the science of geology is much concerned with the age and origin of all rocks to determine the history and formation of Earth and to understand the forces that have acted upon it.
    [Show full text]
  • Neoproterozoic Glaciations in a Revised Global Palaeogeography from the Breakup of Rodinia to the Assembly of Gondwanaland
    Sedimentary Geology 294 (2013) 219–232 Contents lists available at SciVerse ScienceDirect Sedimentary Geology journal homepage: www.elsevier.com/locate/sedgeo Invited review Neoproterozoic glaciations in a revised global palaeogeography from the breakup of Rodinia to the assembly of Gondwanaland Zheng-Xiang Li a,b,⁎, David A.D. Evans b, Galen P. Halverson c,d a ARC Centre of Excellence for Core to Crust Fluid Systems (CCFS) and The Institute for Geoscience Research (TIGeR), Department of Applied Geology, Curtin University, GPO Box U1987, Perth, WA 6845, Australia b Department of Geology and Geophysics, Yale University, New Haven, CT 06520-8109, USA c Earth & Planetary Sciences/GEOTOP, McGill University, 3450 University St., Montreal, Quebec H3A0E8, Canada d Tectonics, Resources and Exploration (TRaX), School of Earth and Environmental Sciences, University of Adelaide, SA 5005, Australia article info abstract Article history: This review paper presents a set of revised global palaeogeographic maps for the 825–540 Ma interval using Received 6 January 2013 the latest palaeomagnetic data, along with lithological information for Neoproterozoic sedimentary basins. Received in revised form 24 May 2013 These maps form the basis for an examination of the relationships between known glacial deposits, Accepted 28 May 2013 palaeolatitude, positions of continental rifting, relative sea-level changes, and major global tectonic events Available online 5 June 2013 such as supercontinent assembly, breakup and superplume events. This analysis reveals several fundamental ’ Editor: J. Knight palaeogeographic features that will help inform and constrain models for Earth s climatic and geodynamic evolution during the Neoproterozoic. First, glacial deposits at or near sea level appear to extend from high Keywords: latitudes into the deep tropics for all three Neoproterozoic ice ages (Sturtian, Marinoan and Gaskiers), al- Neoproterozoic though the Gaskiers interval remains very poorly constrained in both palaeomagnetic data and global Rodinia lithostratigraphic correlations.
    [Show full text]
  • Integrative and Comparative Biology Integrative and Comparative Biology, Volume 58, Number 4, Pp
    Integrative and Comparative Biology Integrative and Comparative Biology, volume 58, number 4, pp. 605–622 doi:10.1093/icb/icy088 Society for Integrative and Comparative Biology SYMPOSIUM INTRODUCTION The Temporal and Environmental Context of Early Animal Evolution: Considering All the Ingredients of an “Explosion” Downloaded from https://academic.oup.com/icb/article-abstract/58/4/605/5056706 by Stanford Medical Center user on 15 October 2018 Erik A. Sperling1 and Richard G. Stockey Department of Geological Sciences, Stanford University, 450 Serra Mall, Building 320, Stanford, CA 94305, USA From the symposium “From Small and Squishy to Big and Armored: Genomic, Ecological and Paleontological Insights into the Early Evolution of Animals” presented at the annual meeting of the Society for Integrative and Comparative Biology, January 3–7, 2018 at San Francisco, California. 1E-mail: [email protected] Synopsis Animals originated and evolved during a unique time in Earth history—the Neoproterozoic Era. This paper aims to discuss (1) when landmark events in early animal evolution occurred, and (2) the environmental context of these evolutionary milestones, and how such factors may have affected ecosystems and body plans. With respect to timing, molecular clock studies—utilizing a diversity of methodologies—agree that animal multicellularity had arisen by 800 million years ago (Ma) (Tonian period), the bilaterian body plan by 650 Ma (Cryogenian), and divergences between sister phyla occurred 560–540 Ma (late Ediacaran). Most purported Tonian and Cryogenian animal body fossils are unlikely to be correctly identified, but independent support for the presence of pre-Ediacaran animals is recorded by organic geochemical biomarkers produced by demosponges.
    [Show full text]
  • Download Download
    Dorjnamjaa et al. Mongolian Geoscientist 49 (2019) 41-49 https://doi.org/10.5564/mgs.v0i49.1226 Mongolian Geoscientist Review paper New scientific direction of the bacterial paleontology in Mongolia: an essence of investigation * Dorj Dorjnamjaa , Gundsambuu Altanshagai, Batkhuyag Enkhbaatar Department of Paleontology, Institute of Paleontology, Mongolian Academy of Sciences, Ulaanbaatar 15160, Mongolia *Corresponding author. Email: [email protected] ARTICLE INFO ABSTRACT Article history: We review the initial development of Bacterial Paleontology in Mongolia and Received 10 September 2019 present some electron microscopic images of fossil bacteria in different stages of Accepted 9 October 2019 preservation in sedimentary rocks. Indeed bacterial paleontology is one the youngest branches of paleontology. It has began in the end of 20th century and has developed rapidly in recent years. The main tasks of bacterial paleontology are detailed investigation of fossil microorganisms, in particular their morphology and sizes, conditions of burial and products of habitation that are reflected in lithological and geochemical features of rocks. Bacterial paleontology deals with fossil materials and is useful in analysis of the genesis of sedimentary rocks, and sedimentary mineral resources including oil and gas. The traditional paleontology is especially significant for evolution theory, biostratigraphy, biogeography and paleoecology; however bacterial paleontology is an essential first of all for sedimentology and for theories sedimentary ore genesis or biometallogeny Keywords: microfossils, phosphorite, sedimentary rocks, lagerstatten, biometallogeny INTRODUCTION all the microorganisms had lived and propagated Bacteria or microbes preserved well as fossils in without breakdowns. Bacterial paleontological various rocks, especially in sedimentary rocks data accompanied by the data on the first origin alike natural substances.
    [Show full text]
  • Geochemical Characteristics of Late Ordovician Shales in the Upper Yangtze Platform, South China: Implications for Redox Environmental Evolution
    minerals Article Geochemical Characteristics of Late Ordovician Shales in the Upper Yangtze Platform, South China: Implications for Redox Environmental Evolution Donglin Lin 1,2,3, Shuheng Tang 1,2,3,*, Zhaodong Xi 1,2,3, Bing Zhang 1,2,3 and Yapei Ye 1,2,3 1 School of Energy Resource, China University of Geosciences, Beijing 100083, China; [email protected] (D.L.); [email protected] (Z.X.); [email protected] (B.Z.); [email protected] (Y.Y.) 2 Key Laboratory of Marine Reservoir Evolution and Hydrocarbon Enrichment Mechanism, Ministry of Education, Beijing 100083, China 3 Key Laboratory of Strategy Evaluation for Shale Gas, Ministry of Land and Resources, Beijing 100083, China * Correspondence: [email protected]; Tel.: +86-134-8882-1576 Abstract: Changes to the redox environment of seawater in the Late Ordovician affect the process of organic matter enrichment and biological evolution. However, the evolution of redox and its underlying causes remain unclear. This paper analyzed the vertical variability of main, trace elements and δ34Spy from a drill core section (well ZY5) in the Upper Yangtze Platform, and described the redox conditions, paleoproductivity and paleoclimate variability recorded in shale deposits of the P. pacificus zone and M. extraordinarius zone that accumulated during Wufeng Formation. The results showed that shale from well ZY5 in Late Ordovician was deposited under oxidized water environment, and Citation: Lin, D.; Tang, S.; Xi, Z.; Zhang, B.; Ye, Y. Geochemical there are more strongly reducing bottom water conditions of the M. extraordinarius zone compared Characteristics of Late Ordovician with the P.
    [Show full text]
  • Jocelyn A. Sessa
    Jocelyn A. Sessa Current: Assistant Curator of Invertebrate Paleontology, Academy of Natural Sciences, & Assistant Professor, Department of Biodiversity, Earth & Environmental Science of Drexel University. Past Positions: 2016 to 2017 Senior Scientist in Paleontology & Education, American Museum of Natural History. Postdoctoral Fellowships: 2012 to 2016 Departments of Paleontology & Education, American Museum of Natural History. 2010 to 2012 Department of Paleobiology, Smithsonian National Museum of Natural History. 2009 to 2010 Department of Earth Sciences, Syracuse University. Education: Ph.D., 2009 Department of Geosciences, Pennsylvania State University, University Park, PA. M.S., 2003 Department of Geology, University of Cincinnati, Cincinnati, Ohio. B.A., 2000 Department of Geological Sciences, State University of New York at Geneseo, Geneseo, NY. Cum laude, minor in Environmental Studies. Publications (* indicates student author; for student work, ‡ indicates corresponding author): Buczek, A.J.*, Hendy, A., Hopkins, M. Sessa, J.A.‡ 2020. On the reconciliation of biostratigraphy and strontium isotope stratigraphy of three southern Californian Plio-Pleistocene formations. Geological Society of America Bulletin 132 ; doi.org/10.1130/B35488.1. Oakes, R.L., Sessa, J.A. 2020. Determining how biotic and abiotic variables affect the shell condition and parameters of Heliconoides inflatus pteropods from a sediment trap in the Cariaco Basin. Biogeosciences 17:1975–1990; doi.org/10.5194/bg-17-1975-2020. Oakes, R.L., Hill Chase, M., Siddall, M.E., Sessa, J.A. 2020. Testing the impact of two key scan parameters on the quality and repeatability of measurements from CT scan data. Palaeontologia Electronica 23(1):a07; doi.org/10.26879/942. Ferguson, K.*, MacLeod, K.G.‡, Landman, N.H., Sessa, J.A.‡ 2019.
    [Show full text]
  • (Silurian) Anoxic Palaeo-Depressions at the Western Margin of the Murzuq Basin (Southwest Libya), Based on Gamma-Ray Spectrometry in Surface Exposures
    GeoArabia, Vol. 11, No. 3, 2006 Gulf PetroLink, Bahrain Identification of early Llandovery (Silurian) anoxic palaeo-depressions at the western margin of the Murzuq Basin (southwest Libya), based on gamma-ray spectrometry in surface exposures Nuri Fello, Sebastian Lüning, Petr Štorch and Jonathan Redfern ABSTRACT Following the melting of the Gondwanan icecap and the resulting postglacial sea- level rise, organic-rich shales were deposited in shelfal palaeo-depressions across North Africa and Arabia during the latest Ordovician to earliest Silurian. The unit is absent on palaeohighs that were flooded only later when the anoxic event had already ended. The regional distribution of the Silurian black shale is now well-known for the subsurface of the central parts of the Murzuq Basin, in Libya, where many exploration wells have been drilled and where the shale represents the main hydrocarbon source rock. On well logs, the Silurian black shale is easily recognisable due to increased uranium concentrations and, therefore, elevated gamma-ray values. The uranium in the shales “precipitated” under oxygen- reduced conditions and generally a linear relationship between uranium and organic content is developed. The distribution of the Silurian organic-rich shales in the outcrop belts surrounding the Murzuq Basin has been long unknown because Saharan surface weathering has commonly destroyed the organic matter and black colour of the shales, making it complicated to identify the previously organic-rich unit in the field. In an attempt to distinguish (previously) organic-rich from organically lean shales at outcrop, seven sections that straddle the Ordovician-Silurian boundary were measured by portable gamma-ray spectrometer along the outcrops of the western margin of the Murzuq Basin.
    [Show full text]
  • Timing and Tempo of the Great Oxidation Event
    Timing and tempo of the Great Oxidation Event Ashley P. Gumsleya,1, Kevin R. Chamberlainb,c, Wouter Bleekerd, Ulf Söderlunda,e, Michiel O. de Kockf, Emilie R. Larssona, and Andrey Bekkerg,f aDepartment of Geology, Lund University, Lund 223 62, Sweden; bDepartment of Geology and Geophysics, University of Wyoming, Laramie, WY 82071; cFaculty of Geology and Geography, Tomsk State University, Tomsk 634050, Russia; dGeological Survey of Canada, Ottawa, ON K1A 0E8, Canada; eDepartment of Geosciences, Swedish Museum of Natural History, Stockholm 104 05, Sweden; fDepartment of Geology, University of Johannesburg, Auckland Park 2006, South Africa; and gDepartment of Earth Sciences, University of California, Riverside, CA 92521 Edited by Mark H. Thiemens, University of California, San Diego, La Jolla, CA, and approved December 27, 2016 (received for review June 11, 2016) The first significant buildup in atmospheric oxygen, the Great situ secondary ion mass spectrometry (SIMS) on microbaddeleyite Oxidation Event (GOE), began in the early Paleoproterozoic in grains coupled with precise isotope dilution thermal ionization association with global glaciations and continued until the end of mass spectrometry (ID-TIMS) and paleomagnetic studies, we re- the Lomagundi carbon isotope excursion ca. 2,060 Ma. The exact solve these uncertainties by obtaining accurate and precise ages timing of and relationships among these events are debated for the volcanic Ongeluk Formation and related intrusions in because of poor age constraints and contradictory stratigraphic South Africa. These ages lead to a more coherent global per- correlations. Here, we show that the first Paleoproterozoic global spective on the timing and tempo of the GOE and associated glaciation and the onset of the GOE occurred between ca.
    [Show full text]
  • A Mesoproterozoic Iron Formation PNAS PLUS
    A Mesoproterozoic iron formation PNAS PLUS Donald E. Canfielda,b,1, Shuichang Zhanga, Huajian Wanga, Xiaomei Wanga, Wenzhi Zhaoa, Jin Sua, Christian J. Bjerrumc, Emma R. Haxenc, and Emma U. Hammarlundb,d aResearch Institute of Petroleum Exploration and Development, China National Petroleum Corporation, 100083 Beijing, China; bInstitute of Biology and Nordcee, University of Southern Denmark, 5230 Odense M, Denmark; cDepartment of Geosciences and Natural Resource Management, Section of Geology, University of Copenhagen, 1350 Copenhagen, Denmark; and dTranslational Cancer Research, Lund University, 223 63 Lund, Sweden Contributed by Donald E. Canfield, February 21, 2018 (sent for review November 27, 2017; reviewed by Andreas Kappler and Kurt O. Konhauser) We describe a 1,400 million-year old (Ma) iron formation (IF) from Understanding the genesis of the Fe minerals in IFs is one step the Xiamaling Formation of the North China Craton. We estimate toward understanding the relationship between IFs and the this IF to have contained at least 520 gigatons of authigenic Fe, chemical and biological environment in which they formed. For comparable in size to many IFs of the Paleoproterozoic Era (2,500– example, the high Fe oxide content of many IFs (e.g., refs. 32, 34, 1,600 Ma). Therefore, substantial IFs formed in the time window and 35) is commonly explained by a reaction between oxygen and between 1,800 and 800 Ma, where they are generally believed to Fe(II) in the upper marine water column, with Fe(II) sourced have been absent. The Xiamaling IF is of exceptionally low thermal from the ocean depths. The oxygen could have come from ex- maturity, allowing the preservation of organic biomarkers and an change equilibrium with oxygen in the atmosphere or from ele- unprecedented view of iron-cycle dynamics during IF emplace- vated oxygen concentrations from cyanobacteria at the water- ment.
    [Show full text]