Abstract
AbstractGraphite formation temperatures in the ‘Los Pobres’ mine within the Ronda peridotite, Spain, previously reported to be between 770 and 820 °C, have been reinterpreted based on new temperature measurements using Raman spectroscopy. Additional in situ and bulk stable carbon isotopic measurements and fluid inclusion studies contributed to improved understanding of parts of the graphite formation process. Raman spectroscopy revealed that the formation of the ‘Los Pobres’ graphite extends to temperatures as low as 500 °C, indicating a broader temperature range than previously reported. Stable carbon isotopes and temperature estimates suggest two different crystallization events, followed by a late hydrothermal alteration of the host rock. The first event occurred at temperatures higher than ∼600°C, in which crystalline graphite was formed with a mixed 13C composition as a result of the mixing of two different carbon-bearing sources. The second graphite formation event took place below ∼600°C, within the same system, but with lower purity and crystallinity of the graphite. In the third event, the temperature decreased to less than 550 °C, and hydrothermal fluids altered the host rock, precipitating silica and iron oxides in veins penetrating both the host rock and the deposited graphite.
Highlights
Carbonaceous matter (CM) subjected to burial and metamorphism undergoes maturation to become well-crystallized graphite
This study aims to reinvestigate the formation of the graphite and evaluate the influences of serpentinization on the paragenesis of the graphite mineralization using Raman spectroscopy and stable carbon isotopes
Raman spectroscopy showed that these veins are mainly composed of secondary amorphous silica, amorphous iron oxyhydroxide and crystalline goethite
Summary
Carbonaceous matter (CM) subjected to burial and metamorphism undergoes maturation to become well-crystallized graphite. Disordered carbonaceous material becomes increasingly ordered with rising temperature (T) and pressure (P). The maturation and graphitization process of carbonaceous matter, allows for the use of carbon disorganization as a metamorphic thermometer. The c0 parameter is an indicator of maximum formation T, but because XRD requires sample disaggregation, sample preparation may alter the CM structure. Using Raman spectroscopy to characterize CM is advantageous (Beyssac et al, 2002a; Huang et al, 2010). When using an Arþ laser, Raman characterization of CM is mainly within the spectroscopic strong first-order bands with wavenumbers between 1000 and 1800 cm–1 (Beyssac et al, 2002a, 2002b; Pimenta et al, 2007; VC The Author(s) 2020.
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