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Fluids in the Crust. Redox effects on calcite-portlandite-fluid equilibria at for earc conditions: Carbon mobility, methanogenesis, and reduction melting of calcite

  • Codi Lazar , Chi Zhang and Craig E. Manning
Published/Copyright: August 12, 2014
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American Mineralogist
From the journal American Mineralogist Volume 99 Issue 8-9

Abstract

Oxygen fugacity (ƒO2) is a fundamental parameter that controls carbon mobility in aqueous fluids in geological environments such as subduction zones, where reduced serpentinite fluids have the potential to infiltrate oxidized carbonate-bearing lithologies. Using experiments and calculations, we describe how mineral-fluid equilibria evolve as ƒO2 decreases in the model Ca- C-O-H system at forearc conditions (300-700 °C and 2-10 kbar). Experimental calcite solubility was constant at ƒO2 values from quartz-fayalite-magnetite (QFM) to hematite-magnetite (HM). At lower ƒO2 values of iron-magnetite (IM) or wüstite-magnetite (WM), calcite reacted with H2 to form methane plus portlandite or melt. These results were consistent with thermodynamic calculations and indicate that carbon mobility, as parameterized by total aqueous carbon ([CTOT]), is strongly dependent on ƒO2. At constant pressure and temperature, carbon mobility is minimized at oxidizing conditions, where [CTOT] is controlled by calcite solubility. Carbon mobility is maximized at the most reducing conditions because all the carbon in the system is present as CH4. An intermediate region of carbon mobility exists in which calcite is stable with a CH4-bearing fluid. As pressure increases from 2 to 10 kbar, the ƒO2 range over which calcite is stable with a methane-rich fluid shifts to more reducing conditions. The variety of geological conditions with the potential for redox enhancement of carbon mobility becomes more restricted with depth. Reduction melting was observed at 700 °C and 6 kbar, and at 650 °C and 10 kbar, due to the partial reaction of calcite to portlandite at conditions above the hydrous melting curve of calcite+portlandite. Although likely metastable in the present experiments, reduction melting may occur in nature whenever H2 partially reduces carbonate minerals at pressures and temperatures above the hydrous melting curve of calcite+portlandite. Whether it causes melting or not, calcite reduction is likely an important mechanism for abiotic methanogenesis in natural systems such as subduction zone forearcs or similar environments with the potential for interaction of reduced fluids with carbonate minerals. Because calcite solubility at oxidized conditions is already known to increase substantially with pressure, the additional increase in carbon mobility provided by calcite reduction implies that subduction zones may host some of the most carbon-rich aqueous fluids on Earth.

Keywords : Carbon cycle; subduction zones; fluid-rock interaction; serpentinization; forearc mantle; methanogenesis
Published Online: 2014-8-12
Published in Print: 2014-8-1

© 2014 by Walter de Gruyter Berlin/Boston

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https://doi.org/10.2138/am.2014.4696
Keywords for this article
Carbon cycle; subduction zones; fluid-rock interaction; serpentinization; forearc mantle; methanogenesis

Articles in the same Issue

  1. Chemistry and Mineralogy of Earth’s Mantle. Evidence for multiple diamondite-forming events in the mantle
  2. Chemistry and Mineralogy of Earth’s Mantle. Evidence for multiple diamondite-forming events in the mantle
  3. Chemistry and Mineralogy of Earth’s Mantle. Experimental determination of melting in the systems enstatite-magnesite and magnesite-calcite from 15 to 80 GPa
  4. Chemistry and Mineralogy of Earth’s Mantle. The spin state of iron in Fe3+-bearing Mg-perovskite and its crystal chemistry at high pressure
  5. Chemistry and Mineralogy of Earth’s Mantle. Hexagonal Na0.41[Na0.125Mg0.79Al0.085]2[Al0.79Si0.21]6O12 (NAL phase): Crystal structure refinement and elasticity
  6. What Lurks in the Martian Rocks and Soil? Investigations of Sulfates, Phosphates, and Perchlorates. Multivariate Analysis of Raman Spectra for the Identification of Sulfates: Implications for ExoMars
  7. What Lurks in the Martian Rocks and Soil? Investigations of Sulfates, Phosphates, and Perchlorates. Spectral and thermal properties of perchlorate salts and implications for Mars
  8. What Lurks in the Martian Rocks and Soil? Investigations of Sulfates, Phosphates, and Perchlorates. Reflectance spectroscopy and optical functions for hydrated Fe-sulfates
  9. Fluids in the Crust. Redox effects on calcite-portlandite-fluid equilibria at for earc conditions: Carbon mobility, methanogenesis, and reduction melting of calcite
  10. Fluids in the Crust. Constraints on the mobilization of Zr in magmatic-hydrothermal processes in subduction zones from in situ fluid-melt partitioning experiments
  11. The Second Conference on the Lunar Highlands Crust and New Directions. The petrogenesis of impact basin melt rocks in lunar meteorite Shişr 161
  12. Amorphous Materials: Properties, structure, and durability. The nearly complete dissociation of water in glasses with strong aluminum avoidance
  13. Sepiolite-palygorskite polysomatic series: Oriented aggregation as a crystal growth mechanism in natural environments
  14. Bentonite evolution at elevated pressures and temperatures: An experimental study for generic nuclear repository designs
  15. Rates of Li diffusion in garnet: Coupled transport of Li and Y+REEs
  16. Characteristics of djerfisherite from fluid-rich, metasomatized alkaline intrusive environments and anhydrous enstatite chondrites and achondrites
  17. Ferroan geikielite and coupled spinel-rutile exsolution from titanohematite: Interface characterization and magnetic properties
  18. Constraints on the incorporation mechanism of chlorine in peralkaline and peraluminous Na2O-CaO-Al2O3-SiO2 glasses
  19. Interlayer structure model of tri-hydrated low-charge smectite by X-ray diffraction and Monte Carlo modeling in the Grand Canonical ensemble
  20. Tetrahedrally coordinated Co2+ in oxides and silicates: Effect of local environment on optical properties
  21. A variable-temperature neutron diffraction study of serandite: A Mn-silicate framework with a very strong, two-proton site, hydrogen bond
  22. A new biogenic, struvite-related phosphate, the ammonium-analog of hazenite, (NH4)NaMg2(PO4)2·14H2O
  23. Chromo-alumino-povondraite, NaCr3(Al4Mg2)(Si6O18)(BO3)3(OH)3O, a new mineral species of the tourmaline supergroup
  24. The occurrence of platinum-group element and gold minerals in the Bon Accord Ni-oxide body, South Africa
  25. Beshtauite, (NH4)2(UO2)(SO4)2·2H2O, a new mineral from Mount Beshtau, Northern Caucasus, Russia
  26. High-pressure phase transitions in FeCr2O4 and structure analysis of new post-spinel FeCr2O4 and Fe2Cr2O5 phases with meteoritical and petrological implications
  27. Letter. Kumdykolite from the ultrahigh-pressure granulite of the Bohemian Massif
  28. Letter. Crystal chemistry of dense hydrous magnesium silicates: The structure of phase H, MgSiH2O4, synthesized at 45 GPa and 1000 °C
  29. New Mineral Names
  30. Book Review
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