Startseite Redox variations in the inner solar system with new constraints from vanadium XANES in spinels
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Redox variations in the inner solar system with new constraints from vanadium XANES in spinels

  • Kevin Righter EMAIL logo , Steve R. Sutton , Lisa Danielson , Kellye Pando und Matt Newville
Veröffentlicht/Copyright: 1. September 2016
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American Mineralogist
Aus der Zeitschrift American Mineralogist Band 101 Heft 9

Abstract

Many igneous rocks contain mineral assemblages that are not appropriate for application of common mineral equilibria or oxybarometers to estimate oxygen fugacity. Spinel-structured oxides, common minerals in many igneous rocks, typically contain sufficient V for XANES measurements, allowing use of the correlation between oxygen fugacity and V K pre-edge peak intensity. Here we report V pre-edge peak intensities for a wide range of spinels from source rocks ranging from terrestrial basalt to achondrites to oxidized chondrites. The XANES measurements are used to calculate oxygen fugacity from experimentally produced spinels of known fo2. We obtain values, in order of increasing fo2, from IW-3 for lodranites and acapulcoites, to diogenites, brachinites (near IW), ALH 84001, terrestrial basalt, hornblende-bearing R chondrite LAP 04840 (IW+1.6), and finally ranging up to IW+3.1 for CK chondrites (where the ΔIW logfo2 of a sample relative to the logfo2 of the IW buffer at specific T). To place the significance of these new measurements into context we then review the range of oxygen fugacities recorded in major achondrite groups, chondritic and primitive materials, and planetary materials. This range extends from IW-8 to IW+2. Several chondrite groups associated with aqueous alteration exhibit values that are slightly higher than this range, suggesting that water and oxidation may be linked. The range in planetary materials is even wider than that defined by meteorite groups. Earth and Mars exhibit values higher than IW+2, due to a critical role played by pressure. Pressure allows dissolution of volatiles into magmas, which can later cause oxidation or reduction during fractionation, cooling, and degassing. Fluid mobility, either in the sub-arc mantle and crust, or in regions of metasomatism, can generate values >IW+2, again suggesting an important link between water and oxidation. At the very least, Earth exhibits a higher range of oxidation than other planets and astromaterials due to the presence of an O-rich atmosphere, liquid water, and hydrated interior. New analytical techniques and sample suites will revolutionize our understanding of oxygen fugacity variation in the inner solar system, and the origin of our solar system in general.

Keywords: Oxygen fugacity; meteorites; solar nebula; spinel; chromite; vanadium; Invited Centennial article

Acknowledgments

This work was supported by an RTOP from the NASA Cosmochemistry/Emerging Worlds programs. Portions of this work were performed at GeoSoilEnviroCARS (Sector 13), Advanced Photon Source (APS), Argonne National Laboratory. Geo-SoilEnviroCARS is supported by the National Science Foundation, Earth Sciences (EAR-1128799) and Department of Energy-GeoSciences (DE-FG02-94ER14466). This research used resources of the Advanced Photon Source, a U.S. Department of Energy (DOE) Office of Science User Facility operated for the DOE Office of Science by Argonne National Laboratory under Contract No. DE-AC02-06CH11357. All meteorite samples were provided by the Meteorite Working Group except for the acapulcoites/lodranites (J. Herrin), GRA 06128 (A. Treiman), and ALH 84001 (M. Righter). The manuscript benefitted from the careful reviews and constructive comments of P. Burger, J. Paque, and AE S. Simon. We thank K. Putirka for the invitation to contribute a paper in celebration of the American Mineralogist centennial, and K.R. acknowledges the enormous and continuing influence the Mineralogical Society of America has had on his science and understanding of the natural world.

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Received: 2015-11-30
Accepted: 2016-4-14
Published Online: 2016-9-1
Published in Print: 2016-9-1

© 2016 by Walter de Gruyter Berlin/Boston

Artikel in diesem Heft

  1. Highlights and Breakthroughs
  2. Styles of aqueous alteration on Mars
  3. Highlights and Breakthroughs
  4. Study on nanophase iron oxyhydroxides in freshwater ferromanganese nodules from Green Bay, Lake Michigan
  5. Review
  6. Redox variations in the inner solar system with new constraints from vanadium XANES in spinels
  7. Special Collection: Apatite: A Common Mineral, Uncommonly Versatile
  8. From bone to fossil: A review of the diagenesis of bioapatite
  9. Special Collection: Olivine
  10. Nickel–cobalt contents of olivine record origins of mantle peridotite and related rocks
  11. Special Collection: Rates And Depths Of Magma Ascent On Earth
  12. Experimental simulation of bubble nucleation and magma ascent in basaltic systems: Implications for Stromboli volcano
  13. Special Collection: Nanominerals and Mineral Nanoparticles
  14. Study on nanophase iron oxyhydroxides in freshwater ferromanganese nodules from Green Bay, Lake Michigan, with implications for the adsorption of As and heavy metals
  15. Special Collection: Building Planets: The Dynamics and Geochemistry of Core Formation
  16. The effects of shear deformation on planetesimal core segregation: Results from in-situ X-ray micro-tomography
  17. Special Collection: Martian Rocks and Minerals: Perspectives from Rovers, Orbiters, and Meteorites
  18. VNIR multispectral observations of aqueous alteration materials by the Pancams on the Spirit and Opportunity Mars Exploration Rovers
  19. Research Article
  20. Experimental investigation of the kinetics of the spinel-to-garnet transformation in peridotite: A preliminary study
  21. Research Article
  22. Thermodynamics, self-diffusion, and structure of liquid NaAlSi3O8 to 30 GPa by classical molecular dynamics simulations
  23. Research Article
  24. Magnetite plaquettes are naturally asymmetric materials in meteorites
  25. Research Article
  26. Rare-earth perovskites along the CaTiO3-Na0.5La0.5TiO3 join: Phase transitions, formation enthalpies, and implications for loparite minerals
  27. Research Article
  28. Kinetics of Fe3+ mineral crystallization from ferrihydrite in the presence of Si at alkaline conditions and implications for nuclear waste disposal
  29. Research Article
  30. Multi-scale three-dimensional characterization of iron particles in dusty olivine: Implications for paleomagnetism of chondritic meteorites
  31. Research Article
  32. Modeling dislocation glide and lattice friction in Mg2SiO4 wadsleyite in conditions of the Earth’s transition zone
  33. Research Article
  34. Carlsonite, (NH4)5Fe33+O(SO4)67H2O , and huizingite-(Al), (NH4)9Al3(SO4)8(OH)2·4H2O, two new minerals from a natural fire in an oil-bearing shale near Milan, Ohio
  35. Research-article
  36. Vránaite, ideally Al16B4Si4O38, a new mineral related to boralsilite, Al16B6Si2O37, from the Manjaka pegmatite, Sahatany Valley, Madagascar
  37. Research-article
  38. Gaussian thermoluminescence in long-range disordered K-feldspar
  39. New Mineral Names
  40. New Mineral Names
  41. Book Review
  42. Book Review: Gems & Crystals From One of the World’s Great Collections
https://doi.org/10.2138/am-2016-5638
Schlagwörter für diesen Artikel
Oxygen fugacity; meteorites; solar nebula; spinel; chromite; vanadium; Invited Centennial article

Artikel in diesem Heft

  1. Highlights and Breakthroughs
  2. Styles of aqueous alteration on Mars
  3. Highlights and Breakthroughs
  4. Study on nanophase iron oxyhydroxides in freshwater ferromanganese nodules from Green Bay, Lake Michigan
  5. Review
  6. Redox variations in the inner solar system with new constraints from vanadium XANES in spinels
  7. Special Collection: Apatite: A Common Mineral, Uncommonly Versatile
  8. From bone to fossil: A review of the diagenesis of bioapatite
  9. Special Collection: Olivine
  10. Nickel–cobalt contents of olivine record origins of mantle peridotite and related rocks
  11. Special Collection: Rates And Depths Of Magma Ascent On Earth
  12. Experimental simulation of bubble nucleation and magma ascent in basaltic systems: Implications for Stromboli volcano
  13. Special Collection: Nanominerals and Mineral Nanoparticles
  14. Study on nanophase iron oxyhydroxides in freshwater ferromanganese nodules from Green Bay, Lake Michigan, with implications for the adsorption of As and heavy metals
  15. Special Collection: Building Planets: The Dynamics and Geochemistry of Core Formation
  16. The effects of shear deformation on planetesimal core segregation: Results from in-situ X-ray micro-tomography
  17. Special Collection: Martian Rocks and Minerals: Perspectives from Rovers, Orbiters, and Meteorites
  18. VNIR multispectral observations of aqueous alteration materials by the Pancams on the Spirit and Opportunity Mars Exploration Rovers
  19. Research Article
  20. Experimental investigation of the kinetics of the spinel-to-garnet transformation in peridotite: A preliminary study
  21. Research Article
  22. Thermodynamics, self-diffusion, and structure of liquid NaAlSi3O8 to 30 GPa by classical molecular dynamics simulations
  23. Research Article
  24. Magnetite plaquettes are naturally asymmetric materials in meteorites
  25. Research Article
  26. Rare-earth perovskites along the CaTiO3-Na0.5La0.5TiO3 join: Phase transitions, formation enthalpies, and implications for loparite minerals
  27. Research Article
  28. Kinetics of Fe3+ mineral crystallization from ferrihydrite in the presence of Si at alkaline conditions and implications for nuclear waste disposal
  29. Research Article
  30. Multi-scale three-dimensional characterization of iron particles in dusty olivine: Implications for paleomagnetism of chondritic meteorites
  31. Research Article
  32. Modeling dislocation glide and lattice friction in Mg2SiO4 wadsleyite in conditions of the Earth’s transition zone
  33. Research Article
  34. Carlsonite, (NH4)5Fe33+O(SO4)67H2O , and huizingite-(Al), (NH4)9Al3(SO4)8(OH)2·4H2O, two new minerals from a natural fire in an oil-bearing shale near Milan, Ohio
  35. Research-article
  36. Vránaite, ideally Al16B4Si4O38, a new mineral related to boralsilite, Al16B6Si2O37, from the Manjaka pegmatite, Sahatany Valley, Madagascar
  37. Research-article
  38. Gaussian thermoluminescence in long-range disordered K-feldspar
  39. New Mineral Names
  40. New Mineral Names
  41. Book Review
  42. Book Review: Gems & Crystals From One of the World’s Great Collections
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