Rare Earth Element Enrichment in Late Archean Manganese Deposits from the Iron Ore Group, East India

Moriyama, Takeru; Panigrahi, M. K.; Pandit, Dinesh; Watanabe, Yasushi

doi:10.1111/j.1751-3928.2008.00072.x

Cited by 13 publications

(7 citation statements)

References 22 publications

(82 reference statements)

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“…It is noteworthy that, the ΣREE contents of these manganese deposits are significantly high, such as Zunyi (ΣREE=509.54 ppm, tuffaceous clay rock=1394 ppm), Shuicheng (ΣREE=712 ppm), Qianxi (ΣREE=1175.11 ppm) and Xuanwei (ΣREE=493 ppm) (Table 4; Liu et al, 2008;Yang et al, 2009;Xu et al, 2018). This is similar to the hydrothermal manganese deposits in Sardinia, Western Italy (REE= 3309.15 ppm) (Mongelli et al, 2013), the Neptuno manganese deposits in the Santa Rosalía basin and adjacent areas in Baja California Sur, México (REE=563.10 ppm) (Del RioSalas et al, 2008), and the late Archean hydrothermal HREE-rich manganese deposit in eastern India (REE highest=563.10 ppm) (Mohapatra et al, 2006;Mishra et al, 2006;Moriyama et al, 2008). Hence, these obvious geological and geochemically characteristics indicate that manganese mineralization and REEs enrichment have been related to hydrothermal activity in Zunyi and its adjacent areas during the middle to late Permian.…”

Section: Sources Of the Rare Earth Elements (Rees)supporting

confidence: 71%

Genesis for Rare Earth Elements Enrichment in the Permian Manganese Deposits in Zunyi, Guizhou Province, SW China

Gao

Yang

et al. 2020

Acta Geologica Sinica (Eng)

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The Zunyi manganese deposits, which formed during the Middle to Late Permian period and are located in northern Guizhou and adjacent areas, are the core area of a series of large‐medium scale manganese enrichment minerogenesis in the southern margin and interior of the Yangtze platform, Southern China. This study reports the universal enrichment of rare earth elements (REEs) in Zunyi manganese deposits and examines the enrichment characteristics, metallogenic environment and genesis of REEs. The manganese ore bodies present stratiform or stratoid in shape, hosted in the silicon–mud–limestones of the Late Permian Maokou Formation. The manganese ores generally present lamellar, massive, banded and brecciated structures, and mainly consist of rhodochrosite, ropperite, tetalite, capillitite, as well as contains paragenetic gangue minerals including pyrite, chalcopyrite, rutile, barite, tuffaceous clay rock, etc. The manganese ores have higher ΣREE contents range from 158 to 1138.9 ppm (average 509.54 ppm). In addition, the ΣREE contents of tuffaceous clay rock in ore beds vary from 1032.2 to 1824.5 ppm (average 1396.42 ppm). The REEs from manganese deposits are characterized by La, Ce, Nd and Y enriched, and existing in the form of independent minerals (e.g., monazite and xenotime), indicating Zunyi manganese deposits enriched in light rare earth elements (LREE). The Ceanom ratios (average –0.13) and lithofacies and paleogeography characteristics indicate that Zunyi manganese deposits were formed in a weak oxidation‐reduction environment. The (La/Yb)ch, Y/Ho, (La/Nd)N, (Dy/Yb)N, Ce/Ce* and Eu/Eu* values of samples from the Zunyi manganese deposits are 5.53–56.92, 18–39, 1.42–3.15, 0.55–2.20, 0.21–1.76 and 0.48–0.86, respectively, indicating a hydrothermal origin for the manganese mineralization and REEs enrichment. The (δ13CV‐PDB (−0.54 to −18.1%) and (δ18OSMOW (21.6 to 26.0%) characteristics of manganese ores reveal a mixed source of magmatic and organic matter. Moreover, the manganese ore, tuffaceous clay rock and Emeishan basalt have extremely similar REE fractionation characteristic, suggesting REEs enrichment and manganese mineralization have been mainly origin from hydrothermal fluids.

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Section: Sources Of the Rare Earth Elements (Rees)supporting

confidence: 71%

Genesis for Rare Earth Elements Enrichment in the Permian Manganese Deposits in Zunyi, Guizhou Province, SW China

Gao

Yang

et al. 2020

Acta Geologica Sinica (Eng)

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“…Indeed, rhodochrosite is a major manganese mineral in hydrothermal manganese deposits (e.g., ref. 47), and Archean manganese-rich rocks show a strong signal of hydrothermal input (48,49). It is worth mentioning that Archean sedimentary rocks have experienced at least low-grade metamorphism which may undermine the preservation of rhodochrosite via decarbonation to form MnO or Mn-silicate, which often cooccurs with rhodochrosite in metamorphosed sediments (50,51).…”

Section: Discussionmentioning

confidence: 99%

Anoxic photogeochemical oxidation of manganese carbonate yields manganese oxide

Liu

Hao

Elzinga

et al. 2020

Proc. Natl. Acad. Sci. U.S.A.

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The oxidation states of manganese minerals in the geological record have been interpreted as proxies for the evolution of molecular oxygen in the Archean eon. Here we report that an Archean manganese mineral, rhodochrosite (MnCO3), can be photochemically oxidized by light under anoxic, abiotic conditions. Rhodochrosite has a calculated bandgap of about 5.4 eV, corresponding to light energy centering around 230 nm. Light at that wavelength would have been present on Earth’s surface in the Archean, prior to the formation of stratospheric ozone. We show experimentally that the photooxidation of rhodochrosite in suspension with light centered at 230 nm produced H2 gas and manganite (γ-MnOOH) with an apparent quantum yield of 1.37 × 10−3 moles hydrogen per moles incident photons. Our results suggest that manganese oxides could have formed abiotically on the surface in shallow waters and on continents during the Archean eon in the absence of molecular oxygen.

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“…Grant et al [37],Avasthy [38],Sarkar [39] and Raha and Moitra [40] reported algal stromatolites and spheroidal & filamentous microfossils in the BIF and manganese ore horizon of the Noamundi basin. Beukes et al [25] studied the Fe-ores of the Noamundi basin and concluded that the original magnetite rich Fe-ore protolith evolved to high grade hematite ore in three stages i.e.…”

Section: Discussionmentioning

confidence: 99%

Iron and Manganese Mineralization Associated with Archean Greenstone Belt in Joda-Noamundi Sector, Odisha, East Indian Shield

Ghosh¹

2015

EARTH

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Iron and manganese mineralization in the Joda-Noamundi sector is associated with Banded Iron Formation of the Archean Iron Ore Group of rocks (3.5-3.0 Ga).Both Mn and Fe mineralization is stratiform and stratabound. In the Noamundi basin the estimated reserve of Fe and Mn-ores are 3.3 Gt and 130 Mt respectively. The Fe and Mn-mineralization are also genetically related to each other. A detailed petrology, mineralogy and mineral chemistry of the ores show their evolution with respect to different tectonic phases. During the first phase of deformation and metamorphism Fe-protolith generated magnetite and Mn-protolth generated bixbyite, hausmannite, jacobsite and braunite. During second phase martitized magnetite and hematite in Fe-ore and hollandite, psilomelane and pyrolusite in Mn-ore were generated. During supergene events low temperature higher oxide minerals were generated from the metamorphic and hydrothermal Fe and Mn-ore minerals. The stratigraphic status of the Fe-and Mn-ores with respect to crustal evolution has been established.

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Rare Earth Element Enrichment in Late Archean Manganese Deposits from the Iron Ore Group, East India

Cited by 13 publications

References 22 publications

Genesis for Rare Earth Elements Enrichment in the Permian Manganese Deposits in Zunyi, Guizhou Province, SW China

Genesis for Rare Earth Elements Enrichment in the Permian Manganese Deposits in Zunyi, Guizhou Province, SW China

Anoxic photogeochemical oxidation of manganese carbonate yields manganese oxide

Iron and Manganese Mineralization Associated with Archean Greenstone Belt in Joda-Noamundi Sector, Odisha, East Indian Shield

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