Gold mineralization in the Ashanti Belt of Ghana; genetic constraints of the stable isotope geochemistry

Oberthuer, Thomas; Mumm, Andreas Schmidt; Vetter, U.; Simon, Klaus; Amanor, J. A.

doi:10.2113/gsecongeo.91.2.289

Cited by 82 publications

(34 citation statements)

References 24 publications

(18 reference statements)

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“…This characteristic reflects the presence of two different fluids within the metallogenic system, that is, a deeply sourced fluid, and a fluid sourced from atmospheric precipitation. Based on the geological conditions for metallogenesis and comparison between the H-O isotopic compositions of the metallogenic fluid and those of orogenic mineral deposits [53][54][55][56][57][58][59][60][61][62][63][64], we deduced that the metallogenic fluid is a mix between deeply sourced fluids and basin brines.…”

Section: H-o Isotopesmentioning

confidence: 99%

Identification of Two Types of Metallogenic Fluids in the Ultra-Large Huize Pb–Zn Deposit, SW China

et al. 2017

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This work investigates the ultra-large Huize Pb-Zn deposit, based on the results of preceding studies and detailed field geological surveys. The existing findings were reorganized and reinterpreted and supplemented with C-H-O isotopic measurements, which resulted in the identification of two different metallogenic fluids: a high temperature, low salinity, and acidic Fluid A, which originates from deep-seated fluids and is enriched in lighter C and O isotopes (−3‰ < 13 C‰ < −4‰; 10‰ < 18 O‰ < 17‰; −92‰ < D‰ < −50‰), and a low temperature, high salinity Fluid B, which is a subsurface brine formed by atmospheric precipitation. Fluid B is characterized by heavier C-O-H isotopic compositions (−2‰ < 13 C‰ < 1‰; 2‰ < 18 O‰ < 24‰; −66‰ < D‰ < −43‰) than Fluid A and cycles continuously within the strata. We hypothesize that the Huize Pb-Zn deposit is the result of large-scale fluid migration from deep regions of the crust. These upward-moving fluids extracted metallic elements from carbonate strata of various ages, forming a metal-rich metallogenic fluid (Fluid A). After higher-grade ores were precipitated from the fluid following decompression boiling, it then mixed with Fluid B and continued to precipitate sulfides.

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Section: H-o Isotopesmentioning

confidence: 99%

Identification of Two Types of Metallogenic Fluids in the Ultra-Large Huize Pb–Zn Deposit, SW China

et al. 2017

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“…The extent of this event suggests that it is related to regional crustal processes. A crustal origin of the mineralizing fluids is also favoured by OberthuÈr et al (1996) based on extensive stable isotope studies.…”

Section: Origin Of Carbonic Fluid Inclusions In the Hamadi Gold Depositmentioning

confidence: 99%

Carbonic fluids in the Hamadi gold deposit, Sudan: origin and contribution to gold mineralization

Cheng

Wang

et al. 2017

Can. J. Earth Sci.

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The Hamadi gold deposit is located in North Sudan, and occurs in the Neoproterozoic metamorphic strata of the Arabian–Nubian Shield. Two types of gold mineralization can be discerned: gold-bearing quartz veins and altered rock ores near ductile shear zones. The gold-bearing quartz veins are composed of white to gray quartz associated with small amounts of pyrite and other polymetallic sulfide minerals. Wall-rock alterations include mainly beresitization, epidotization, chloritization, and carbonatization. CO2-rich inclusions are commonly seen in gold-bearing quartz veins and quartz veinlets from gold-bearing altered rocks; these include mainly one-phase carbonic (CO2 ± CH4 ± N2) inclusions and CO2–H2O inclusions with CO2/H2O volumetric ratios of 30% to ∼80%. Laser Raman analysis does not show the H2O peak in carbonic inclusions. In quartz veins, the melting temperature of solid CO2 (Tm,CO2) of carbonic inclusions has a narrow range of −59.6 to −56.8 °C. Carbonic inclusions also have CO2 partial homogenization temperatures (Th,CO2) of −28.3 to +23.7 °C, with most of the values clustering between +4.0 and +20 °C; all of these inclusions are homogenized into the liquid CO2 state. The densities range from 0.73 to 1.03 g/cm3. XCH4 of carbonic fluid inclusions ranges from 0.004 to 0.14, with most XCH4 around 0.05. In CO2–H2O fluid inclusions, Tm,CO2 values are recorded mostly at around −57.5 °C. The melting temperature of clathrate is 3.8–8.9 °C. It is suggested that the lowest trapping pressures of CO2 fluids would be 100 to ∼400 MPa, on the basis of the Th,CO2 of CO2-bearing one-phase (LCO2) inclusions and the total homogenization temperatures (Th,tot) of paragenetic CO2-bearing two-phase (LCO2–LH2O) inclusions. For altered rocks, the Tm,CO2 of the carbonic inclusions has a narrow range of −58.4 to ∼−57.0 °C, whereas the Th,CO2 varies widely (−19 to ∼+29 °C). Most carbonic inclusions and the carbonic phases in the CO2–H2O inclusions are homogenized to liquid CO2 phases, which correspond to densities of 0.70 to ∼1.00 g/cm3. Fluid inclusions in a single fluid inclusion assemblage (FIA) have narrow Tm,CO2 and Th,CO2 values, but they vary widely in different FIAs and non-FIAs, which indicates that there was a wide range of trapping pressure and temperature (P–T) conditions during the ore-forming process in late retrograde metamorphism after the metamorphism peak period. The carbonic inclusions in the Hamadi gold deposit are interpreted to have resulted from unmixing of an originally homogeneous aqueous–carbonic mixture during retrogress metamorphism caused by decreasing P–T conditions. CO2 contributed to gold mineralization by buffering the pH range and increasing the gold concentration in the fluids.

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“…Schmidt-Mumm et al (1997) argue in favor of a mineralizing fluid essentially composed of CO 2 with variable proportions of N 2 . The elevated volatile content and the isotopic data from the inclusions suggest a deep origin of the fluids (Oberthü r et al, 1996). Schmidt-Mumm (1998) also attributed the chemical nature of the fluid to devolatilization at depth and fluid focusing into shear zones without re-equilibration with the country rock.…”

Section: Fluid Source and Pressure-temperature Conditionsmentioning

confidence: 99%

Gold metallogeny in the Birimian craton of Burkina Faso (West Africa)

Béziat

Dubois

Debat

et al. 2008

Journal of African Earth Sciences

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Gold mineralization in the Ashanti Belt of Ghana; genetic constraints of the stable isotope geochemistry

Cited by 82 publications

References 24 publications

Identification of Two Types of Metallogenic Fluids in the Ultra-Large Huize Pb–Zn Deposit, SW China

Identification of Two Types of Metallogenic Fluids in the Ultra-Large Huize Pb–Zn Deposit, SW China

Carbonic fluids in the Hamadi gold deposit, Sudan: origin and contribution to gold mineralization

Gold metallogeny in the Birimian craton of Burkina Faso (West Africa)

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