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Dissolution rates of amorphous Al- and Fe-phosphates and their relevance to phosphate mobility on Mars

  • Valerie M. Tu , Elisabeth M. Hausrath EMAIL logo , Oliver Tschauner , Valentin Iota and Gerald W. Egeland
Published/Copyright: July 2, 2014
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American Mineralogist
From the journal American Mineralogist Volume 99 Issue 7

Abstract

Phosphate is an essential nutrient for life on Earth, and therefore if life exists or ever existed on Mars it may have required phosphate. Amorphous Al- and Fe-phosphates rapidly precipitate from acidic solutions and amorphous Al-phosphates likely control phosphate concentrations in some natural waters on Earth. The amorphous fraction of martian soils has also been shown to be enriched in P, and amorphous phosphates are therefore also likely important in the phosphate cycle on Mars. Despite this importance, however, few dissolution rates exist for amorphous Al- and Fe-phosphates. In this study, dissolution rates of amorphous Al- and Fe-phosphates were measured in flow-through reactors from steady state concentrations of Al, Fe, and P. A pH-dependent rate law, log R = log k - npH was determined from the dissolution rates, where R is the dissolution rate, k is the intrinsic rate constant, and n is the reaction order with respect to H+. For amorphous Al-phosphate, log k = -6.539 ± 1.529 and n = 2.391 ± 0.493. For amorphous Fe-phosphate, log k = -13.031 ± 0.558 and n = 1.376 ± 0.221. The amorphous Al-phosphate dissolves stoichiometrically under all experimental conditions measured, and the amorphous Fe-phosphate dissolves non-stoichiometrically, approaching stoichiometric dissolution as pH decreases, due potentially to Fe oxyhydroxides precipitating and armoring grain surfaces. Perhaps due to these effects, amorphous Al-phosphate dissolution rates are approximately three orders of magnitude faster than the amorphous Fe-phosphate dissolution rates measured under these experimental conditions. Amorphous Al-phosphate dissolution rates measured in this study are also faster than published dissolution rates for the crystalline Al-phosphate variscite. The rapid dissolution rates measured in this study therefore suggest that, if these phases are present on Mars, phosphate would be rapidly released into acidic environments.

Keywords: Phosphate; Mars; mineral dissolution; kinetics; habitability; astrobiology; amorphous phases; synchotron
Published Online: 2014-7-2
Published in Print: 2014-7-1

© 2014 by Walter de Gruyter Berlin/Boston

Articles in the same Issue

  1. Highlights and Breakthroughs
  2. An alternative to alteration and melting processes in the Earth: Reaction between hydrogen (H2) and oxide components in the Earth in space and time
  3. The crystallographic and petrogenetic significance of pegmatite phosphates
  4. Small grains and big implications: Accessory Ti- and Zr-minerals as petrogenetic indicators in HP and UHP marbles
  5. What Lurks in the Martian Rocks and Soil? Investigations of Sulfates, Phosphates, and Perchlorates
  6. Natural Fe-bearing oxides and sulfates from the Rio Tinto Mars analog site: Critical assessment of VNIR reflectance spectroscopy, laser Raman spectroscopy, and XRD as mineral identification tools
  7. Dissolution rates of amorphous Al- and Fe-phosphates and their relevance to phosphate mobility on Mars
  8. Stability and spectroscopy of Mg sulfate minerals: Role of hydration on sulfur isotope partitioning
  9. Synthesis and characterization of the Mars-relevant phosphate minerals Fe- and Mg-whitlockite and merrillite and a possible mechanism that maintains charge balance during whitlockite to merrillite transformation
  10. Minerals in the Human Body
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  17. Identifying the spin transition in Fe2+-rich MgSiO3 perovskite from X-ray diffraction and vibrational spectroscopy
  18. Mantle-derived guyanaite in a Cr-omphacitite xenolith from Moses Rock diatreme, Utah
  19. Pluton assembly and the genesis of granitic magmas: Insights from the GIC pluton in cross section, Sierra Nevada Batholith, California
  20. First-principles molecular dynamics simulations of MgSiO3 glass: Structure, density, and elasticity at high pressure
  21. A new UHP metamorphic complex in the ~1.8 Ga Nagssugtoqidian Orogen of West Greenland
  22. Visible and short-wave infrared reflectance spectroscopy of REE fluorocarbonates
  23. Volatile abundances of coexisting merrillite and apatite in the martian meteorite Shergotty: Implications for merrillite in hydrous magmas
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  29. Z-contrast imaging and ab initio study on “d” superstructure in sedimentary dolomite
  30. Influence of temperature, pressure, and chemical composition on the electrical conductivity of granite
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  32. Ab initio thermodynamic and thermophysical properties of sapphirine end-members in the join Mg4Al8Si2O20-Mg3Al10SiO20
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  34. Natural analogs of belite sulfoaluminate cement clinkers from Negev Desert, Israel
  35. Australian sedimentary opal-A and its associated minerals: Implications for natural silica sphere formation
  36. The 2H and 3R polytypes of sabieite, NH4Fe3+(SO4)2, from a natural fire in an oil-bearing shale near Milan, Ohio
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  39. New Mineral Names
  40. Book Review
https://doi.org/10.2138/am.2014.4613
Keywords for this article
Phosphate; Mars; mineral dissolution; kinetics; habitability; astrobiology; amorphous phases; synchotron

Articles in the same Issue

  1. Highlights and Breakthroughs
  2. An alternative to alteration and melting processes in the Earth: Reaction between hydrogen (H2) and oxide components in the Earth in space and time
  3. The crystallographic and petrogenetic significance of pegmatite phosphates
  4. Small grains and big implications: Accessory Ti- and Zr-minerals as petrogenetic indicators in HP and UHP marbles
  5. What Lurks in the Martian Rocks and Soil? Investigations of Sulfates, Phosphates, and Perchlorates
  6. Natural Fe-bearing oxides and sulfates from the Rio Tinto Mars analog site: Critical assessment of VNIR reflectance spectroscopy, laser Raman spectroscopy, and XRD as mineral identification tools
  7. Dissolution rates of amorphous Al- and Fe-phosphates and their relevance to phosphate mobility on Mars
  8. Stability and spectroscopy of Mg sulfate minerals: Role of hydration on sulfur isotope partitioning
  9. Synthesis and characterization of the Mars-relevant phosphate minerals Fe- and Mg-whitlockite and merrillite and a possible mechanism that maintains charge balance during whitlockite to merrillite transformation
  10. Minerals in the Human Body
  11. Determination of the concentration of asbestos minerals in highly contaminated mine tailings: An example from abandoned mine waste of Crètaz and Èmarese (Valle d’Aosta, Italy)
  12. Spinels Renaissance: The past, present, and future of those ubiquitous minerals and materials
  13. Pressure-volume equation of state for chromite and magnesiochromite: A single-crystal X-ray diffraction investigation
  14. The systematics of the spinel-type minerals: An overview
  15. Chemistry and Mineralogy of Earth’s Mantle
  16. Formation of SiH4 and H2O by the dissolution of quartz in H2 fluid under high pressure and temperature
  17. Identifying the spin transition in Fe2+-rich MgSiO3 perovskite from X-ray diffraction and vibrational spectroscopy
  18. Mantle-derived guyanaite in a Cr-omphacitite xenolith from Moses Rock diatreme, Utah
  19. Pluton assembly and the genesis of granitic magmas: Insights from the GIC pluton in cross section, Sierra Nevada Batholith, California
  20. First-principles molecular dynamics simulations of MgSiO3 glass: Structure, density, and elasticity at high pressure
  21. A new UHP metamorphic complex in the ~1.8 Ga Nagssugtoqidian Orogen of West Greenland
  22. Visible and short-wave infrared reflectance spectroscopy of REE fluorocarbonates
  23. Volatile abundances of coexisting merrillite and apatite in the martian meteorite Shergotty: Implications for merrillite in hydrous magmas
  24. Sb5+ and Sb3+ substitution in segnitite: A new sink for As and Sb in the environment and implications for acid mine drainage
  25. First-principles elasticity of monocarboaluminate hydrates
  26. Substitution of Ti3+ and Ti4+ in hibonite (CaAl12O19)
  27. Exploring the effect of lithium on pegmatitic textures: An experimental study
  28. XANES measurements of Cr valence in olivine and their applications to planetary basalts
  29. Z-contrast imaging and ab initio study on “d” superstructure in sedimentary dolomite
  30. Influence of temperature, pressure, and chemical composition on the electrical conductivity of granite
  31. Ti- and Zr-minerals in calcite-dolomite marbles from the ultrahigh-pressure Kimi Complex, Rhodope mountains, Greece: Implications for the P-T evolution based on reaction textures, petrogenetic grids, and geothermobarometry
  32. Ab initio thermodynamic and thermophysical properties of sapphirine end-members in the join Mg4Al8Si2O20-Mg3Al10SiO20
  33. The relation between Li ↔ Na substitution and hydrogen bonding in five-periodic singlechain silicates nambulite and marsturite: A single-crystal X-ray study
  34. Natural analogs of belite sulfoaluminate cement clinkers from Negev Desert, Israel
  35. Australian sedimentary opal-A and its associated minerals: Implications for natural silica sphere formation
  36. The 2H and 3R polytypes of sabieite, NH4Fe3+(SO4)2, from a natural fire in an oil-bearing shale near Milan, Ohio
  37. Letter
  38. Te-rich raspite, Pb(W0.56Te0.44)O4, from Tombstone, Arizona, U.S.A.: The first natural example of Te6+ substitution for W6+
  39. New Mineral Names
  40. Book Review
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