Insight into the Origin of Iron Ore Based on Elemental Contents of Magnetite and Whole-Rock Geochemistry: A Case of the Bipindi Banded Iron Formations, Nyong Complex, SW Cameroon

Landry Soh Tamehe, Huan Li, Sylvestre Ganno, Zuxing Chen, Yanick Brice Lemdjou, Safiyanu Muhammad Elatikpo

Journal of Earth Science ›› 2024, Vol. 35 ›› Issue (1) : 16-28. DOI: 10.1007/s12583-022-1622-4
Geochemistry and Mineral Deposits

Insight into the Origin of Iron Ore Based on Elemental Contents of Magnetite and Whole-Rock Geochemistry: A Case of the Bipindi Banded Iron Formations, Nyong Complex, SW Cameroon

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Abstract

The Bipindi iron ore district is located in the central section of the Nyong Complex at the northwestern margin of the Congo Craton in Southwest Cameroon. This iron district contains numerous iron mineralization hosted by the Mewongo, Bibole, Kouambo, and Zambi banded iron formations (BIFs). These BIFs contain magnetite as the main iron ore mineral associated with pyrite, and gangue minerals are quartz with minor chlorite and amphibole. The origin of iron ore from these BIFs was investigated using a combination of in-situ magnetite and whole-rock chemistry. The studied BIF ore samples have a narrow range of TFe between 30.90 wt.% and 43.20 wt.%, indicating a low-grade ore. The geochemical signatures of magnetite such as low contents of base metals (e.g., Cu, Co, V, and Zn) and low Co/Zn ratios < 0.85 indicate a hydrothermal origin. Combined with the geochemical features of these BIFs, e. g., high Fe/Ti and Fe/Al ratios (mean > 600 and > 75, respectively), we suggest that magnetite was derived from a mixture of seawater and ∼0.1% low-temperature hydrothermal fluids in an oxidizing environment. Collectively, low-temperature hydrothermal and later metamorphic fluids were necessary for the transformation of the protolith Nyong Complex BIFs to iron ore.

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banded iron formations / iron ore / geochemistry / Congo Craton / trace element composition / LA-ICP-MS

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Landry Soh Tamehe, Huan Li, Sylvestre Ganno, Zuxing Chen, Yanick Brice Lemdjou, Safiyanu Muhammad Elatikpo. Insight into the Origin of Iron Ore Based on Elemental Contents of Magnetite and Whole-Rock Geochemistry: A Case of the Bipindi Banded Iron Formations, Nyong Complex, SW Cameroon. Journal of Earth Science, 2024, 35(1): 16‒28 https://doi.org/10.1007/s12583-022-1622-4

References

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[]
Alexander B W, Bau M, Andersson P, et al.. Continentally-Derived Solutes in Shallow Archean Seawater: Rare Earth Element and Nd Isotope Evidence in Iron Formation from the 2.9 Ga Pongola Supergroup, South Africa. Geochimica et Cosmochimica Acta, 2008, 72(2): 378-394,
CrossRef Google scholar
[]
Bau M, Dulski P. Distribution of Yttrium and Rare-Earth Elements in the Penge and Kuruman Iron-Formations, Transvaal Supergroup, South Africa. Precambrian Research, 1996, 79(1/2): 37-55,
CrossRef Google scholar
[]
Bekker A, Planavsky N J, Krapež B, et al.. Iron Formations: Their Origins and Implications for Ancient Seawater Chemistry. Treatise on Geochemistry, 2014 Amsterdam Elsevier 561-628,
CrossRef Google scholar
[]
Bhattacharya H N, Chakraborty I, Ghosh K K. Geochemistry of some Banded Iron-Formations of the Archean Supracrustals, Jharkhand-Orissa Region, India. Journal of Earth System Science, 2007, 116(3): 245-259,
CrossRef Google scholar
[]
Bolhar R, Kamber B S, Moorbath S, et al.. Characterisation of Early Archaean Chemical Sediments by Trace Element Signatures. Earth and Planetary Science Letters, 2004, 222(1): 43-60,
CrossRef Google scholar
[]
Canil D, Grondahl C, Lacourse T, et al.. Trace Elements in Magnetite from Porphyry Cu-Mo-Au Deposits in British Columbia, Canada. Ore Geology Reviews, 2016, 72: 1116-1128,
CrossRef Google scholar
[]
Chen W T, Zhou M F, Li X C, et al.. In-situ LA-ICP-MS Trace Elemental Analyses of Magnetite: Cu-(Au, Fe) Deposits in the Khetri Copper Belt in Rajasthan Province, NW India. Ore Geology Reviews, 2015, 65: 929-939,
CrossRef Google scholar
[]
Choi J H, Hariya Y. Geochemistry and Depositional Environment of Mn Oxide Deposits in the Tokoro Belt, Northeastern Hokkaido, Japan. Economic Geology, 1992, 87(5): 1265-1274,
CrossRef Google scholar
[]
Chombong N N, Suh C E. 2 883 Ma Commencement of BIF Deposition at the Northern Edge of Congo Craton, Southern Cameroon: New Zircon SHRIMP Data Constraint from Metavolcanics. Episodes, 2013, 36(1): 47-57,
CrossRef Google scholar
[]
Chung D, Zhou M F, Gao J F, et al.. In-situ LA-ICP-MS Trace Elemental Analyses of Magnetite: The Late Palaeoproterozoic Sokoman Iron Formation in the Labrador Trough, Canada. Ore Geology Reviews, 2015, 65: 917-928,
CrossRef Google scholar
[]
Dai Y P. . The Archean Two-Stage BIF Deposition and Genesis of High-Grade Iron Ores in the Anshan-Benxi Area, 2014 Xuzhou Graduate School of the Chinese Academy of Sciences (in Chinese with English Abstract)
[]
Dare S A S, Barnes S J, Beaudoin G, et al.. Trace Elements in Magnetite as Petrogenetic Indicators. Mineralium Deposita, 2014, 49(7): 785-796,
CrossRef Google scholar
[]
Deassou Sezine E, Soh Tamehe L, Ganno S, et al.. Geochronological and Geochemical Constraints for the Metavolcanosedimentary Succession of the Nyong Complex, Northwestern Margin of the Congo Craton: Implications for Depositional Age and Tectonic Setting of Associated Banded Iron Formations. Precambrian Research, 2022, 383: 106910,
CrossRef Google scholar
[]
Djoukouo Soh A P, Ganno S, Zhang L C, et al.. Origin, Tectonic Environment and Age of the Bibole Banded Iron Formations, Northwestern Congo Craton, Cameroon: Geochemical and Geochronological Constraints. Geological Magazine, 2021, 158(12): 2245-2263,
CrossRef Google scholar
[]
Dymek R F, Klein C. Chemistry, Petrology and Origin of Banded Iron-Formation Lithologies from the 3800 MA Isua Supracrustal Belt, West Greenland. Precambrian Research, 1988, 39(4): 247-302,
CrossRef Google scholar
[]
Ganno S, Moudioh C, Nzina Nchare A, et al.. Geochemical Fingerprint and Iron Ore Potential of the Siliceous Itabirite from Palaeoproterozoic Nyong Series, Zambi Area, Southwestern Cameroon. Resource Geology, 2016, 66(1): 71-80,
CrossRef Google scholar
[]
Ganno S, Njiosseu Tanko E L, Kouankap Nono G D, et al.. A Mixed Seawater and Hydrothermal Origin of Superior-Type Banded Iron Formation (BIF)-Hosted Kouambo Iron Deposit, Palaeoproterozoic Nyong Series, Southwestern Cameroon: Constraints from Petrography and Geochemistry. Ore Geology Reviews, 2017, 80: 860-875,
CrossRef Google scholar
[]
Gurvich E G. . Metalliferous Sediments of the World Ocean: Fundamental Theory of Deep-Sea Hydrothermal Sedimentation, 2006 Berlin Springer
[]
Hagemann S G, Angerer T, Duuring P, et al.. BIF-Hosted Iron Mineral System: A Review. Ore Geology Reviews, 2016, 76: 317-359,
CrossRef Google scholar
[]
Hensler A S, Hagemann S G, Rosière C A, et al.. Hydrothermal and Metamorphic Fluid-Rock Interaction Associated with Hypogene “Hard” Iron Ore Mineralisation in the Quadrilátero Ferrífero, Brazil: Implications from in-situ Laser Ablation ICP-MS Iron Oxide Chemistry. Ore Geology Reviews, 2015, 69: 325-351,
CrossRef Google scholar
[]
Houketchang Bouyo M, Penaye J, Mouri H, et al.. Eclogite Facies Metabasites from the Paleoproterozoic Nyong Group, SW Cameroon: Mineralogical Evidence and Implications for a High-Pressure Metamorphism Related to a Subduction Zone at the NW Margin of the Archean Congo Craton. Journal of African Earth Sciences, 2019, 149: 215-234,
CrossRef Google scholar
[]
Hu H, Lentz D, Li J W, et al.. Re-Equilibration Processes of Magnetite from Iron Skarn Deposits. Acta Geologica Sinica: English Edition, 2014, 88(s2): 354-356,
CrossRef Google scholar
[]
Hu H, Li J W, Harlov D E, et al.. A Genetic Link between Iron Oxide-Apatite and Iron Skarn Mineralization in the Jinniu Volcanic Basin, Daye District, Eastern China: Evidence from Magnetite Geochemistry and Multi-Mineral U-Pb Geochronology. GSA Bulletin, 2020, 132(5/6): 899-917,
CrossRef Google scholar
[]
Knipping J L, Bilenker L D, Simon A C, et al.. Trace Elements in Magnetite from Massive Iron Oxide-Apatite Deposits Indicate a Combined Formation by Igneous and Magmatic-Hydrothermal Processes. Geochimica et Cosmochimica Acta, 2015, 171: 15-38,
CrossRef Google scholar
[]
Kwamou W M M, Djibril K N G, Guimollaire N D, et al.. Petrogenesis and U-Pb Zircon Dating of Amphibolite in the Mewengo Iron Deposit, Nyong Series, Cameroon: Fingerprints of Iron Depositional Geotectonic Setting. Arabian Journal of Geosciences, 2021, 14(10): 872,
CrossRef Google scholar
[]
Lerouge C, Cocherie A, Toteu S F, et al.. Shrimp U-Pb Zircon Age Evidence for Paleoproterozoic Sedimentation and 2.05 Ga Syntectonic Plutonism in the Nyong Group, South-Western Cameroon: Consequences for the Eburnean-Transamazonian Belt of NE Brazil and Central Africa. Journal of African Earth Sciences, 2006, 44(4/5): 413-27,
CrossRef Google scholar
[]
Li H M, Zhang Z J, Li L X, et al.. Types and General Characteristics of the BIF-Related Iron Deposits in China. Ore Geology Reviews, 2014, 57: 264-287,
CrossRef Google scholar
[]
Li Y L, Konhauser K O, Zhai M G. The Formation of Magnetite in the Early Archean Oceans. Earth and Planetary Science Letters, 2017, 466: 103-114,
CrossRef Google scholar
[]
Liu L, Zhang H S, Yang X Y, et al.. Age, Origin and Significance of the Wugang BIF in the Taihua Complex, Southern North China Craton. Ore Geology Reviews, 2018, 95: 880-898,
CrossRef Google scholar
[]
Liu L, Zhang L C, Dai Y P. Formation Age and Genesis of the Banded Iron Formations from the Guyang Greenstone Belt, Western North China Craton. Ore Geology Reviews, 2014, 63: 388-404,
CrossRef Google scholar
[]
Liu Y S, Hu Z C, Gao S, et al.. In situ Analysis of Major and Trace Elements of Anhydrous Minerals by LA-ICP-MS without Applying an Internal Standard. Chemical Geology, 2008, 257(1/2): 34-43,
CrossRef Google scholar
[]
Loose D, Schenk V. 2.09 Ga Old Eclogites in the Eburnian-Transamazonian Orogen of Southern Cameroon: Significance for Palaeoproterozoic Plate Tectonics. Precambrian Research, 2018, 304: 1-11,
CrossRef Google scholar
[]
Manikyamba C, Balaram V, Naqvi S M. Geochemical Signatures of Polygenetic Origin of a Banded Iron Formation (BIF) of the Archaean Sandur Greenstone Belt (Schist Belt) Karnataka Nucleus, India. Precambrian Research, 1993, 61(1/2): 137-164,
CrossRef Google scholar
[]
Moudioh C, Soh Tamehe L, Ganno S, et al.. Tectonic Setting of the Bipindi Greenstone Belt, Northwest Congo Craton, Cameroon: Implications on BIF Deposition. Journal of African Earth Sciences, 2020, 171: 103971,
CrossRef Google scholar
[]
Nadoll P, Angerer T, Mauk J L, et al.. The Chemistry of Hydrothermal Magnetite: A Review. Ore Geology Reviews, 2014, 61: 132,
CrossRef Google scholar
[]
Ndime E N, Ganno S, Nzenti J P. Geochemistry and Pb-Pb Geochronology of the Neoarchean Nkout West Metamorphosed Banded Iron Formation, Southern Cameroon. International Journal of Earth Sciences, 2019, 108(5): 1551-1570,
CrossRef Google scholar
[]
Ndime E N, Ganno S, Soh Tamehe L, et al.. Petrography, Lithostratigraphy and Major Element Geochemistry of Mesoarchean Metamorphosed Banded Iron Formation-Hosted Nkout Iron Ore Deposit, North Western Congo Craton, Central West Africa. Journal of African Earth Sciences, 2018, 148: 80-98,
CrossRef Google scholar
[]
Nielsen R L, Forsythe L M, Gallahan W E, et al.. Major- and Trace-Element Magnetite-Melt Equilibria. Chemical Geology, 1994, 117(1/2/3/4): 167-191,
CrossRef Google scholar
[]
Nzepang Tankwa M, Ganno S, Okunlola O A, et al.. Petrogenesis and Tectonic Setting of the Paleoproterozoic Kelle Bidjoka Iron Formations, Nyong Group Greenstone Belts, Southwestern Cameroon. Constraints from Petrology, Geochemistry, and LA-ICP-MS Zircon U-Pb Geochronology. International Geology Review, 2021, 63(14): 1737-1757,
CrossRef Google scholar
[]
Rosière C A, Santos J O S, Silveira Braga F, et al.. Multiple Hydrothermal Iron-Formation Upgrading Events in Southeastern São Francisco Craton. Journal of Geology, 2021, 129(3): 283-296,
CrossRef Google scholar
[]
Rudnick R L, Gao S. Composition of the Continental Crust. Treatise on Geochemistry, 2003 Amsterdam Elsevier 1-64
[]
Silveira Braga F C, Rosière C A, Schneider Santos J O, et al.. Geochemical and Tectonic Constraints on the Genesis of Iron Formation-Hosted Magnetite-Hematite Deposits at the Guanhães Block (Brazil) by Contact Metasomatism with Pegmatite Intrusions. Ore Geology Reviews, 2021, 129: 103931,
CrossRef Google scholar
[]
Soh Tamehe L. . Geology and Genesis of the Gouap Banded Iron Formation (BIF)-Hosted Iron Deposit, South Cameroon, 2020 Xuzhou China University of Mining and Technology
[]
Soh Tamehe L, Nzepang Tankwa M, Wei C T, et al.. Geology and Geochemical Constrains on the Origin and Depositional Setting of the Kpwa-Atog Boga Banded Iron Formations (BIFs), Northwestern Congo Craton, Southern Cameroon. Ore Geology Reviews, 2018, 95: 620-638,
CrossRef Google scholar
[]
Soh Tamehe L, Wei C T, Ganno S, et al.. Geology of the Gouap Iron Deposit, Congo Craton, Southern Cameroon: Implications for Iron Ore Exploration. Ore Geology Reviews, 2019, 107: 1097-1128,
CrossRef Google scholar
[]
Soh Tamehe L, Wei C T, Ganno S, et al.. Depositional Age and Tectonic Environment of the Gouap Banded Iron Formations from the Nyong Group, SW Cameroon: Insights from Isotopic, Geochemical and Geochronological Studies of Drillcore Samples. Geoscience Frontiers, 2021, 12(2): 549-572,
CrossRef Google scholar
[]
Soh Tamehe L, Wei C T, Ganno S, et al.. Provenance of Metasiliciclastic Rocks at the Northwestern Margin of the East Gabonian Block: Implications for Deposition of BIFs and Crustal Evolution in Southwestern Cameroon. Precambrian Research, 2022, 376: 106677,
CrossRef Google scholar
[]
Song Z, Li H M, Li L X, et al.. Iron Isotopes and Trace Element Compositions of Magnetite from the Submarine Volcanic-Hosted Iron Deposits in East Tianshan, NW China: New Insights into the Mineralization Processes. Journal of Earth Science, 2021, 32(1): 219-234,
CrossRef Google scholar
[]
Spier C A, de Oliveira S M B, Rosière C A, et al.. Mineralogy and Trace-Element Geochemistry of the High-Grade Iron Ores of the Águas Claras Mine and Comparison with the Capão Xavier and Tamanduá Iron Ore Deposits, Quadrilátero Ferrífero, Brazil. Mineralium Deposita, 2008, 43(2): 229-254,
CrossRef Google scholar
[]
Sun X H, Zhu X Q, Tang H S, et al.. In situ LA-ICP-MS Trace Element Analysis of Magnetite from the Late Neoarchean Gongchangling BIFs, NE China: Constraints on the Genesis of High-Grade Iron Ore. Geological Journal, 2017, 53(S1): 8-20,
CrossRef Google scholar
[]
Sun Z Y, Wang Y W, Long L L. In-situ LA-ICP-MS Trace Element and Oxygen Isotope Signatures of Magnetite from the Yamansu Deposit, NW China, and Their Significance. Acta Geochimica, 2020, 39(5): 599-615,
CrossRef Google scholar
[]
Swiffa Fajong I, Nzepang Tankwa M, Fossi D H, et al.. Lithostratigraphy, Origin, and Geodynamic Setting of Iron Formations and Host Rocks of the Anyouzok Region, Congo Craton, Southwestern Cameroon. Minerals, 2022, 12(10): 1198,
CrossRef Google scholar
[]
Teutsong T, Bontognali T R R, Ndjigui P D, et al.. 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: 267-288,
CrossRef Google scholar
[]
Teutsong T, Temga J P, Enyegue A A, et al.. Petrographic and Geochemical Characterization of Weathered Materials Developed on BIF from the Mamelles Iron Ore Deposit in the Nyong Unit, South-West Cameroon. Acta Geochimica, 2021, 40(2): 163-175,
CrossRef Google scholar
[]
Toteu S F, Van Schmus W R, Penaye J, et al.. U-Pb and Sm-N Edvidence for Eburnian and Pan-African High-Grade Metamorphism in Cratonic Rocks of Southern Cameroon. Precambrian Research, 1994, 67(3/4): 321-347,
CrossRef Google scholar
[]
Toth J. Deposition of Submarine Crusts Rich in Manganese and Iron. Geological Society of America Bulletin, 1980, 91: 44-54,
CrossRef Google scholar
[]
Trendall A F. Altermann W, Corcoran P L. The Significance of Iron-Formation in the Precambrian Stratigraphic Record. Precambrian Sedimentary Environments: A Modern Approach to Ancient Depositional Systems, 2002 Oxford Blackwell Publishing Ltd. 33-66,
CrossRef Google scholar
[]
Tsoungui P N E, Ganno S, Njiosseu E L T, et al.. Geochemical Constraints on the Origin and Tectonic Setting of the Serpentinized Peridotites from the Paleoproterozoic Nyong Series, Eseka Area, SW Cameroon. Acta Geochimica, 2020, 39(3): 404-422,
CrossRef Google scholar
[]
Verlaguet A, Brunet F, Goffé B, et al.. Experimental Study and Modeling of Fluid Reaction Paths in the Quartz-Kyanite ± Muscovite-Water System at 0.7 GPa in the 350–550 ·C Range: Implications for Al Selective Transfer during Metamorphism. Geochimica et Cosmochimica Acta, 2006, 70(7): 1772-1788,
CrossRef Google scholar
[]
Wang C L, Konhauser K O, Zhang L C. Depositional Environment of the Paleoproterozoic Yuanjiacun Banded Iron Formation in Shanxi Province, China. Economic Geology, 2015, 110(6): 1515-1539,
CrossRef Google scholar
[]
Zhao L D, Chen H Y, Zhang L, et al.. Magnetite Geochemistry of the Heijianshan Fe-Cu (-Au) Deposit in Eastern Tianshan: Metallogenic Implications for Submarine Volcanic-Hosted Fe-Cu Deposits in NW China. Ore Geology Reviews, 2018, 100: 422-440,
CrossRef Google scholar
[]
Zhou Z J, Tang H S, Chen Y J, et al.. Trace Elements of Magnetite and Iron Isotopes of the Zankan Iron Deposit, Westernmost Kunlun, China: A Case Study of Seafloor Hydrothermal Iron Deposits. Ore Geology Reviews, 2017, 80: 1191-1205,
CrossRef Google scholar

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