Transformation of Fe-bearing minerals from Dongsheng sandstone-type uranium deposit, Ordos Basin, north-central China; implications for ore genesis

• Published in: The American mineralogist Vol. 107; no. 7; pp. 1396 - 1409
• Main Authors: Yue Liang, Yue Liang, Jiao Yangquan, Jiao Yangquan, Fayek, Mostafa, Wu Liqun, Wu Liqun, Rong Hui, Rong Hui, Xie Huili, Xie Huili
• Format: Journal Article
• Language: English
• Published: Washington Mineralogical Society of America 01.07.2022; Walter de Gruyter GmbH
• Subjects: actinides; alteration; Asia; Biotite; China; Chlorite; clastic rocks; Clay minerals; Distribution patterns; Dongsheng Deposit; Economic geology; Far East; Fe-bearing minerals; Fluids; Goethite; Haematite; Hematite; Iron; iron minerals; iron oxides; isotope ratios; isotopes; Jurassic; Mesozoic; metal ores; metals; Middle Jurassic; migration of elements; Mineral assemblages; mineral deposits, genesis; Mineralization; Minerals; Ordos Basin; Organic matter; Ostwald ripening; Oxidation; Oxides; Oxidoreductions; Pyrite; S-34/S-32; Sandstone; sandstone-type deposits; sandstone-type U deposit; Sedimentary rocks; Sediments; stable isotopes; Sulfate reduction; sulfides; Sulfur; Sulphate reduction; Sulphur; Titanium; titanium ores; transformations; Uranium; uranium ores; Zhiluo Formation; Ordos Basin
• ISSN: 0003-004X; 1945-3027
• DOI: 10.2138/am-2021-7888

Iron-bearing mineral assemblages and their distribution patterns directly reflect the redox environment in sediments, which plays a decisive role in the migration and precipitation of U. The Dongsheng sandstone-type U deposit hosted in fluvial and/or deltaic sandstones of the lower member of the Middle Jurassic Zhiluo Formation in the northeastern Ordos Basin has experienced multiple fluid events that impacted the redox conditions. Highly enriched in barren gray sandstones, pre-ore U (Umean = 12.05 ppm) associated with Fe-Ti oxides, clay minerals, and organic matter is likely one of the key sources of U for the mineralization. Different contents of Fe-bearing minerals, including biotite, Fe-Ti oxides, pyrite, hematite, goethite, and chlorite that were formed or altered under different redox conditions, resulted in sandstone units with distinct colors. The red sandstone is hematite-rich, indicating a highly oxidizing environment. The green sandstone is chlorite-rich and formed because of reducing hydrocarbon-rich fluids that overprinted the hematite-rich sandstone. The barren and mineralized gray sandstones consist of pyrite (with a higher content in mineralized sandstones), Fe-Ti oxides, and carbonaceous debris, which are indicators of a reducing environment. Based on the paragenetic relationship and sulfur isotopic compositions of ore-stage pyrite, bacterial sulfate reduction was responsible for the formation of framboidal pyrite (δ34S = -31.2 to -3.8 ppm), and the sulfur of this pyrite mainly came from the oxidation of pre-ore pyrite (δ34S = -19.1 to +20.3 ppm). Euhedral and cement pyrite overprinting framboids were produced via Ostwald ripening with δ34S values ranging from -56.9 to -34.3 ppm, lower than any values of framboidal pyrite. Therefore, these mineralogical and geochemical characteristics of the Dongsheng deposit suggest U mineralization involves both biogenic and abiogenic redox processes.