Simulating Precambrian banded iron formation diagenesis

Posth, Nicole R.; Köhler, Inga; Swanner, Elizabeth D.; Schröder, Christian; Wellmann, Eva; Binder, Bernd R.; Konhauser, Kurt O.; Neumann, Udo; Berthold, Christoph; Nowak, Marcus; Kappler, Andreas

doi:10.1016/j.chemgeo.2013.05.031

Cited by 89 publications

(76 citation statements)

References 95 publications

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“…Kennedy et al showed that pure ferrihydrite transformed to haematite at 80°C, whereas it remained stable when associated with bacteria at the same temperature 38 . Using experimental conditions similar to ours, Posth et al 29 demonstrated that, after 14 days at 170°C-120 MPa, ferrihydrite alone transformed to haematite while ferrihydrite associated with glucose completely transformed to haematite, magnetite and siderite 29 . Interestingly, biogenic ferrihydrite recovered at deep-sea hydrothermal vents was preserved after heating 20 min up to 400°C and transformed to haematite only at 500°C (ref.…”

Section: Discussionmentioning

confidence: 98%

Experimental diagenesis of organo-mineral structures formed by microaerophilic Fe(II)-oxidizing bacteria

et al. 2015

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Twisted stalks are organo-mineral structures produced by some microaerophilic Fe(II)-oxidizing bacteria at O 2 concentrations as low as 3 mM. The presence of these structures in rocks having experienced a diagenetic history could indicate microbial Fe(II)-oxidizing activity as well as localized abundance of oxygen at the time of sediment deposition. Here we use spectroscopy and analytical microscopy to evaluate if-and what kind of-transformations occur in twisted stalks through experimental diagenesis. Unique mineral textures appear on stalks as temperature and pressure conditions increase. Haematite and magnetite form from ferrihydrite at 170°C-120 MPa. Yet the twisted morphology of the stalks, and the organic matrix, mainly composed of long-chain saturated aliphatic compounds, are preserved at 250°C-140 MPa. Our results suggest that iron minerals might play a role in maintaining the structural and chemical integrity of stalks under diagenetic conditions and provide spectroscopic signatures for the search of ancient life in the rock record.

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Section: Discussionmentioning

confidence: 98%

Experimental diagenesis of organo-mineral structures formed by microaerophilic Fe(II)-oxidizing bacteria

et al. 2015

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“…Capsules were subjected for 14 days at 170¼C and 1.2 kbar, approximately the diagenetic pressure and temperature (P-T) conditions of one of the largest and most studied iron formations on Earth, the Transvaal Supergroup BIF (Miyano and Klein, 1984;Miyano, 1987). Furthermore, these conditions mimic previous diagenetic capsule experiments (Posth et al, 2013b;Kšhler et al, 2013), and therefore, facilitate a ready comparison between experimental conditions. Our experimental duration and P-T parameters are obviously much abbreviated compared to natural burial diagenesis and metamorphism that takes thousands to millions of years; and are less than experienced by some IF which were subjected to amphibolite facies.…”

Section: Simulated Diagenesis Experimentsmentioning

confidence: 99%

“…Diagenetic capsule experiments on synthetic Fe oxyhydroxide precipitates (Posth et al, 2013b) demonstrate that the Fe mineralogy observed in IF today can be reproduced after incubation of synthetic 2-line ferrihydrite in the presence or absence of glucose (as a proxy for biomass). Capsules were subjected for 14 days at 170¼C and 1.2 kbar, approximately the diagenetic pressure and temperature (P-T) conditions of one of the largest and most studied iron formations on Earth, the Transvaal Supergroup BIF (Miyano and Klein, 1984;Miyano, 1987).…”

Section: Simulated Diagenesis Experimentsmentioning

confidence: 99%

“…Diagenetic experiments and analysis were performed at the University of TŸbingen using similar procedures and apparatus as per Posth et al (2013b were excluded from further analysis as the integrity of the seals were compromised during diagenetic treatments. Finally, the prefix C-denotes a control capsule (e.g., CZnFh1).…”

Section: Simulated Diagenesis Experimentsmentioning

confidence: 99%

“…However, the extent to which Zn and Ni are mobilized when the precursor ferrihydrite underwent reduction and dehydration during diagenesis remains unclear. Our work builds on methodologies of previous simulated IF diagenesis experiments that focused on Fe-mineral transformations (Posth et al, 2013b;Kšhler et al, 2013), in order to evaluate trace element mobilization during diagenesis and the robustness of previous paleomarine Zn and Ni estimates. Additionally, due to the role of organic matter as a diagenetic reductant, we consider reactions between organic carbon and Fe(III) in our diagenetic experiments; with Zn or Ni sorbed to either synthetic 2-line ferrihydrite with added glucose in the capsule or sorbed directly to biogenic ferrihydrite.…”

Section: Introductionmentioning

confidence: 99%

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Limited Zn and Ni mobility during simulated iron formation diagenesis

et al. 2015

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Low‐Fe(III) Greenalite Was a Primary Mineral From Neoarchean Oceans

Johnson

Muhling

Cosmidis

et al. 2018

Geophysical Research Letters

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Banded iron formations (BIFs) represent chemical precipitation from Earth's early oceans and therefore contain insights into ancient marine biogeochemistry. However, BIFs have undergone multiple episodes of alteration, making it difficult to assess the primary mineral assemblage. Nanoscale mineral inclusions from 2.5 billion year old BIFs and ferruginous cherts provide new evidence that iron silicates were primary minerals deposited from the Neoarchean ocean, contrasting sharply with current models for BIF inception. Here we used multiscale imaging and spectroscopic techniques to characterize the best preserved examples of these inclusions. Our integrated results demonstrate that these early minerals were low‐Fe(III) greenalite. We present potential pathways in which low‐Fe(III) greenalite could have formed through changes in saturation state and/or iron oxidation and reduction. Future constraints for ancient ocean chemistry and early life's activities should include low‐Fe(III) greenalite as a primary mineral in the Neoarchean ocean.

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Simulating Precambrian banded iron formation diagenesis

Cited by 89 publications

References 95 publications

Experimental diagenesis of organo-mineral structures formed by microaerophilic Fe(II)-oxidizing bacteria

Experimental diagenesis of organo-mineral structures formed by microaerophilic Fe(II)-oxidizing bacteria

Limited Zn and Ni mobility during simulated iron formation diagenesis

Low‐Fe(III) Greenalite Was a Primary Mineral From Neoarchean Oceans

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