Skip to Main Content
Skip Nav Destination

Replacement origin for hematite in 2.5 Ga banded iron formation: Evidence for postdepositional oxidation of iron-bearing minerals

GSA Bulletin (2014) 126 (3-4): 438–446.
This article has been cited by the following articles in journals that are participating in CrossRef Cited-by Linking.
Snapshot of a Paleoarchean seafloor: Evidence from 3.43-3.35 Ga Strelley Pool chert-pebble conglomerate for deposition, silicification, and erosion of hydrothermal greenalite-apatite precipitates
Precambrian Research (2024) 412: 107531.
Redbed diagenesis links district-scale mineralising fluids to Cu source rock in the Polaris Zn-Pb(-Cu) district, Arctic Canada
Ore Geology Reviews (2024) 165: 105916.
High-grade metamorphism of banded iron formations: the role of saline fluids in promoting the growth of pyroxene and garnet reaction textures along magnetite-quartz grain boundaries
Mineralogy and Petrology (2024) 118 (2): 185.
Episodic hydrothermal supply and microbial anaerobic Fe(II) oxidation in early Archean ocean: Insights from precursor mineral compositions of the 3.46 Ga Marble Bar Chert, Pilbara Craton, Western Australia
Precambrian Research (2024) 410: 107484.
How does weathering influence geochemical proxies in Paleoproterozoic banded iron formations? A case study from outcrop samples of 2.46 Ga banded iron formation, Hamersley Basin, Western Australia
Geological Society of America Bulletin (2024) 136 (7-8): 2735.
Mineralogy of the 1.45 Ga Wafangzi manganese deposit in North China: Implications for pulsed Mesoproterozoic oxygenation events
American Mineralogist (2024) 109 (4): 764.
Genesis of the Neoarchean Algoma-type banded iron formation: constraints from Fe isotope and element geochemistry of the Qian’an iron deposit, eastern North China craton
Precambrian Research (2024) 410: 107480.
Reconstructing diagenetic mineral reactions from silicified horizons of the Paleoproterozoic Biwabik Iron Formation, Minnesota
American Mineralogist (2024) 109 (2): 339.
Nanoparticulate apatite and greenalite in oldest, well-preserved hydrothermal vent precipitates
Science Advances (2024) 10 (4)
Tectonic fluid expulsion: U-Pb evidence for punctuated hydrothermal fluid flow and hydraulic fracturing during orogenesis
Earth and Planetary Science Letters (2023) 604: 117997.
Hydrothermal vent fluid-seawater mixing and the origins of Archean iron formation
Geochimica et Cosmochimica Acta (2023) 352: 51.
Evidence for abundant organic matter in a Neoarchean banded iron formation
American Mineralogist (2023) 108 (12): 2164.
Archean to early Paleoproterozoic iron formations document a transition in iron oxidation mechanisms
Geochimica et Cosmochimica Acta (2023) 343: 286.
Isotopic Constraints on the Nature of Primary Precipitates in Archean–Early Paleoproterozoic Iron Formations from Determinations of the Iron Phonon Density of States of Greenalite and 2L- and 6L-Ferrihydrite
ACS Earth and Space Chemistry (2023) 7 (4): 712.
Logan Medallist 8. Trace Elements in Iron Formation as a Window into Biogeochemical Evolution Accompanying the Oxygenation of Earth’s Atmosphere
Geoscience Canada (2023) 50 (4): 239.
Exploring the secondary mineral products generated by microbial iron respiration in Archean ocean simulations
Geobiology (2022) 20 (6): 743.
The Magnetic and Color Reflectance Properties of Hematite: From Earth to Mars
Reviews of Geophysics (2022) 60 (1)
Comment on “Early Archean biogeochemical iron cycling and nutrient availability: New insights from a 3.5 Ga land-sea transition” by Clark M. Johnson, Xin-Yuan Zheng, Tara Djokic, Martin J. Van Kranendonk, Andrew D. Czaja, Eric E. Roden, Brian L. Beard, 2022, Earth-Science Reviews, https://doi.org/10.1016/j.earscirev.2022.103992
Earth-Science Reviews (2022) 231: 104088.
Structural and hydrothermal evolution of the shear-zone-related iron-oxide enrichment in metavolcano-sedimentary rocks of the intracontinental araçuaí orogen: The case of the espírito santo iron deposit
Ore Geology Reviews (2022) 140: 103719.
Marine phosphate availability and the chemical origins of life on Earth
Nature Communications (2022) 13 (1)
Iron isotope fractionation in anoxygenic phototrophic Fe(II) oxidation by Rhodobacter ferrooxidans SW2
Geochimica et Cosmochimica Acta (2022) 332: 355.
A benthic oxygen oasis in the early Neoproterozoic ocean
Precambrian Research (2021) 355: 106085.
Greenalite and its role in the genesis of early Precambrian iron formations – A review
Earth-Science Reviews (2021) 217: 103613.
Hydrothermal formation of iron-oxyhydroxide chimney mounds in a shallow semi-enclosed bay at Satsuma Iwo-Jima Island, Kagoshima, Japan
GSA Bulletin (2021) 133 (9-10): 1890.
Microbial processes during deposition and diagenesis of Banded Iron Formations
PalZ (2021) 95 (4): 593.
Depositional and Environmental Constraints on the Late Neoarchean Dagushan Deposit (Anshan-Benxi Area, North China Craton): An Algoma-Type Banded Iron Formation
Economic Geology (2021) 116 (7): 1575.
The Yunmengshan iron formation at the end of the Paleoproterozoic era
Applied Clay Science (2020) 199: 105888.
Life on a Mesoarchean marine shelf – insights from the world’s oldest known granular iron formation
Scientific Reports (2020) 10 (1)
Hematite replacement and oxidative overprinting recorded in the 1.88 Ga Gunflint iron formation, Ontario, Canada
Geology (2020) 48 (7): 688.
Archean to Paleoproterozoic seawater halogen ratios recorded by fluid inclusions in chert and hydrothermal quartz
American Mineralogist (2020) 105 (9): 1317.
The biogeochemistry of ferruginous lakes and past ferruginous oceans
Earth-Science Reviews (2020) 211: 103430.
Geochemical constraints on the genesis of the Ekou banded iron formation, Shanxi Province, North China
International Journal of Earth Sciences (2020) 109 (8): 2851.
Widespread deposition of greenalite to form Banded Iron Formations before the Great Oxidation Event
Precambrian Research (2020) 339: 105619.
Hydrogeological constraints on the formation of Palaeoproterozoic banded iron formations
Nature Geoscience (2019) 12 (7): 558.
Iron isotope exchange and fractionation between hematite (α-Fe2O3) and aqueous Fe(II): A combined three-isotope and reversal-approach to equilibrium study
Geochimica et Cosmochimica Acta (2019) 245: 207.
Products of the iron cycle on the early Earth
Free Radical Biology and Medicine (2019) 140: 138.
Syn-tectonic hematite growth in Paleoproterozoic Stirling Range “red beds”, Albany-Fraser Orogen, Australia: Evidence for oxidation during late-stage orogenic uplift
Precambrian Research (2019) 321: 54.
From minerals to metabolisms: Evidence for life before oxygen from the geological record
Free Radical Biology and Medicine (2019) 140: 126.
In-situ LA-ICP-MS and EMP trace element analyses of hematite: Insight into the geochemical signature of the Neoproterozoic Urucum iron formation, Brazil
Journal of South American Earth Sciences (2019) 96: 102313.
Nickel and iron partitioning between clay minerals, Fe-oxides and Fe-sulfides in lagoon sediments from New Caledonia
Science of The Total Environment (2019) 689: 1212.
The metallogenic environment of the Dounan manganese deposit, Southeast Yunnan, China: evidence from geochemistry and Mössbauer spectroscopic
Acta Geochimica (2019) 38 (1): 78.
A new appraisal of depositional cyclicity in the Neoarchean-Paleoproterozoic Dales Gorge Member (Brockman Iron Formation, Hamersley Basin, Australia)
Precambrian Research (2019) 328: 27.
Making magnetite late again: Evidence for widespread magnetite growth by thermal decomposition of siderite in Hamersley banded iron formations
Precambrian Research (2018) 306: 64.
Mineral transformations during thermal demagnetization of sideritic jasper mesobands in jaspilites of the ~3.25 Ga Fig Tree Group in the Barberton Greenstone Belt, Kaapvaal craton (South Africa)
South African Journal of Geology (2018) 121 (2): 131.
Fe isotopes of a 2.4 Ga hematite-rich IF constrain marine redox conditions around the GOE
Precambrian Research (2018) 305: 218.
Sedimentary mechanisms of a modern banded iron formation on Milos Island, Greece
Solid Earth (2018) 9 (3): 573.
Differentiation of ironstone types by using rare earth elements and yttrium geochemistry – A case study from the Bahariya region, Egypt
Ore Geology Reviews (2018) 96: 247.
Geneses and evolutions of iron-bearing minerals in banded iron formations of >3760 to ca. 2200 million-year-old: Constraints from electron microscopic, X-ray diffraction and Mössbauer spectroscopic investigations
Precambrian Research (2017) 289: 1.
Petrography and geochemistry of the Mesoarchean Bikoula banded iron formation in the Ntem complex (Congo craton), Southern Cameroon: Implications for its origin
Ore Geology Reviews (2017) 80: 267.
Iron formations: A global record of Neoarchaean to Palaeoproterozoic environmental history
Earth-Science Reviews (2017) 172: 140.
Close Modal

or Create an Account

Close Modal
Close Modal