Silician Magnetite from the Copiapó Nordeste Prospect of Northern Chile and Its Implication for Ore-Forming Conditions of Iron Oxide–Copper–Gold Deposits

Silica-bearing magnetite was recognized in the Copiapó Nordeste prospect as the first documented occurrence in Chilean iron oxide–copper–gold (IOCG) deposits. The SiO2-rich magnetite termed silician magnetite occurs in early calcic to potassic alteration zones as orderly oscillatory layers in polyhedral magnetite and as isolated discrete grains, displaying perceptible optical differences in color and reflectance compared to normal magnetite. Micro-X-ray fluorescence and electron microprobe analyses reveal that silician magnetite has a significant SiO2 content with small amounts of other “impure” components, such as Al2O3, CaO, MgO, TiO2, and MnO. The oscillatory-zoned magnetite is generally enriched in SiO2 (up to 7.5 wt %) compared to the discrete grains. The formation of silician magnetite is explained by the exchange reactions between 2Fe (III) and Si (IV) + Fe (II), with the subordinate reactions between Fe (III) and Al (III) and between 2Fe (II) and Ca (II) + Mg (II). Silician magnetite with high concentrations of SiO2 (3.8–8.9 wt %) was similarly noted in intrusion-related magmatic–hydrothermal deposits including porphyry- and skarn-type deposits. This characteristic suggests that a hydrothermal system of relatively high-temperature and hypersaline fluids could be a substantial factor in the formation of silician magnetite with high SiO2 contents.

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On the origin of oldest Iron-Oxide-Copper-Gold (IOCG) deposits at the transition from Archean drip to plate tectonics

10.21203/rs.3.rs-50946/v1 ◽

2020 ◽

Author(s):

Carlos E Ganade ◽

William L. Griffin ◽

Roberto F. Weinberg ◽

Elena Belousova ◽

Lynthener B. Takenaka ◽

...

Keyword(s):

Iron Oxide ◽

Lithospheric Mantle ◽

Plate Tectonics ◽

Isotopic Signature ◽

Trace Element Composition ◽

Gold Deposits ◽

Detrital Zircons ◽

Geological Evidence ◽

Iocg Deposits ◽

Copper Gold

Abstract Geological evidence supports a significant change in Earth’s behaviour in the mid- to late Archaean, between 3.2 and 2.5 Ga, reflecting stabilization of the lithosphere and replacement of vertical tectonics by linear imbricated belts. At the heart of this change, the oldest (c. 2.75 Ga) Iron-Oxide-Copper-Gold deposits (IOCG) were formed in the Carajás Mineral Province (CMP) of the Amazon craton. U-Pb ages, Lu-Hf isotopes and trace element composition of detrital zircons from modern drainages record the crystallization ages of the exposed rocks of the CMP. Combined with the geochemistry of Archean granitoids in the CMP, we recognize four different age and compositional groups: 3.01-2.92 Ga TTG, 2.87-2.83 Ga transitional TTG + sanukitoid + K-rich granitoids, 2.78-2.72 Ga A-type crustal granites accompanying IOCGs, and 2.59-2.53 Ga alkaline high-K intrusions accompanied by renewed IOCG mineralization. The first two groups have a dominantly juvenile isotopic signature whereas the last two have evolved Hf-isotope signatures, accompanied by increase in K2O/Na2O, reflecting addition of old crustal components in the melting sources over time. The older juvenile granitoids are associated with dome-and-keel structures typical of granite-greenstone terranes, whereas the younger granitoids were emplaced along a linear shear belt associated with new mafic-ultramafic intrusions and remelting of older TTG. Based on the tectono-magmatic evolution, we argue that metasomatism and fertilization of the underlying lithospheric mantle by incompatible elements, necessary for the development of IOCG deposits, were related to vertical drip-tectonics during development of the TTG proto-continent. This proto-continent made the lithosphere rigid enough to allow linear translithospheric deformation to localize at c. 2.85 Ga, allowing decompression melting of the metasomatized lithospheric mantle in a restricted extensional setting to form abundant mafic and A-type granitoids at c. 2.75 Ga, and the first IOCG deposits on Earth.

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Exploration guidelines for copper-rich iron oxide–copper–gold deposits in the Mantoverde area, northern Chile: the integration of host-rock molar element ratios and oxygen isotope compositions

Geochemistry Exploration Environment Analysis ◽

10.1144/1467-7873/07-165 ◽

2008 ◽

Vol 8 (3-4) ◽

pp. 343-367 ◽

Cited By ~ 11

Author(s):

Jorge Benavides ◽

T. Kurt Kyser ◽

Alan H. Clark ◽

Clifford Stanley ◽

Christopher Oates

Keyword(s):

Iron Oxide ◽

Oxygen Isotope ◽

Host Rock ◽

Gold Deposits ◽

Northern Chile ◽

Element Ratios ◽

Copper Gold

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Noble gas and halogen constraints on fluid sources in iron oxide-copper-gold mineralization: Mantoverde and La Candelaria, Northern Chile

Mineralium Deposita ◽

10.1007/s00126-014-0548-x ◽

2014 ◽

Vol 50 (3) ◽

pp. 357-371 ◽

Cited By ~ 5

Author(s):

Robert Marschik ◽

Mark A. Kendrick

Keyword(s):

Iron Oxide ◽

Gold Mineralization ◽

Noble Gas ◽

Northern Chile ◽

Copper Gold ◽

Fluid Sources

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Evidence of multiple halogen sources in scapolites from iron oxide-copper-gold (IOCG) deposits and regional Na Cl metasomatic alteration, Norrbotten County, Sweden

Chemical Geology ◽

10.1016/j.chemgeo.2017.01.005 ◽

2017 ◽

Vol 451 ◽

pp. 90-103 ◽

Cited By ~ 10

Author(s):

Nelson F. Bernal ◽

Sarah A. Gleeson ◽

Martin P. Smith ◽

Jaime D. Barnes ◽

Yuanming Pan

Keyword(s):

Iron Oxide ◽

Metasomatic Alteration ◽

Iocg Deposits ◽

Copper Gold

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MAPPING THE MINERAL ZONATION AT THE ERNEST HENRY IRON OXIDE COPPER-GOLD DEPOSIT: VECTORING TO Cu-Au MINERALIZATION USING MODAL MINERALOGY

Economic Geology ◽

10.5382/econgeo.4915 ◽

2022 ◽

Vol 117 (2) ◽

pp. 485-494

Author(s):

Tobias U. Schlegel ◽

Renee Birchall ◽

Tina D. Shelton ◽

James R. Austin

Keyword(s):

Iron Oxide ◽

Gamma Ray ◽

Geochemical Data ◽

Iocg Deposits ◽

Mineral Mapping ◽

Gamma Ray Spectrometer ◽

Mineral Assemblages ◽

Copper Gold ◽

Host Rocks ◽

Acid Alteration

Abstract Iron oxide copper-gold (IOCG) deposits form in spatial and genetic relation to hydrothermal iron oxide-alkali-calcic-hydrolytic alteration and thus show a mappable zonation of mineral assemblages toward the orebody. The mineral zonation of a breccia matrix-hosted orebody is efficiently mapped by regularly spaced samples analyzed by the scanning electron microscopy-integrated mineral analyzer technique. The method results in quantitative estimates of the mineralogy and allows the reliable recognition of characteristic alteration as well as mineralization-related mineral assemblages from detailed mineral maps. The Ernest Henry deposit is located in the Cloncurry district of Queensland and is one of Australia’s significant IOCG deposits. It is known for its association of K-feldspar altered clasts with iron oxides and chalcopyrite in the breccia matrix. Our mineral mapping approach shows that the hydrothermal alteration resulted in a characteristic zonation of minerals radiating outward from the pipe-shaped orebody. The mineral zonation is the result of a sequence of sodic alteration followed by potassic alteration, brecciation, and, finally, by hydrolytic (acid) alteration. The hydrolytic alteration primarily affected the breccia matrix and was related to economic mineralization. Alteration halos of individual minerals such as pyrite and apatite extend dozens to hundreds of meters beyond the limits of the orebody into the host rocks. Likewise, the Fe-Mg ratio in hydrothermal chlorites changes systematically with respect to their distance from the orebody. Geochemical data obtained from portable X-ray fluorescence (p-XRF) and petrophysical data acquired from a magnetic susceptibility meter and a gamma-ray spectrometer support the mineralogical data and help to accurately identify mineral halos in rocks surrounding the ore zone. Specifically, the combination of mineralogical data with multielement data such as P, Mn, As, P, and U obtained from p-XRF and positive U anomalies from radiometric measurements has potential to direct an exploration program toward higher Cu-Au grades.

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