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References

  • Alexander C. M. O'D. 1994. Trace element distributions within ordinary chondrite chondrules: Implications for chondrule formation conditions and precursors. Geochimica et Cosmochimica Acta 58:34513467.
  • Alexander C. M. O'D. and Wang J. 2001. Iron isotopes in chondrules: Implications for the role of evaporation during chondrule formation. Meteoritics & Planetary Science 36:419428.
  • Anand M., Russell S. S., Blackhurst R. L., and Grady M. M. 2006. Searching for signatures of life on Mars: An Fe-isotope perspective. Philosophical Transactions of the Royal Society of London Series B, Biological Sciences 361:17151720.
  • Anders E. and Ebihara M. 1982. Solar-system abundances of the elements. Geochimica et Cosmochimica Acta 46:23632380.
  • Anders E. and Grevesse N. 1989. Abundances of the elements: Meteoritic and solar. Geochimica et Cosmochimica Acta 53:197214.
  • Barrat J. A., Zanda B., Moynier F., Bollinger C., Liorzou C., and Bayon G. 2012. Geochemistry of CI chondrites: Major and trace elements, and Cu and Zn isotopes. Geochimica et Cosmochimica Acta 83:7992.
  • Berlin J. 2009. Mineralogy and bulk chemistry of chondrules and matrix in petrologic type 3 chondrites: Implications for early solar system processes. Ph.D. thesis, The University of New Mexico, Albuquerque, NM, USA.
  • Clayton D. D. 2003. Handbook of isotopes in the cosmos: Hydrogen to gallium. Cambridge: Cambridge University Press. 328 p.
  • Craddock P. R. and Dauphas N. 2011. Iron isotopic compositions of geological reference materials and chondrites. Geostandards and Geoanalytical Research 35:101123.
  • Crozaz G. and Wadhwa M. 2001. The terrestrial alteration of Saharan shergottites Dar al Gani 476 and 489: A case study of weathering in a hot desert environment. Geochimica et Cosmochimica Acta 65:971977.
  • Dauphas N., Janney P. E., Mendybaev R. A., Wadhwa M., Richter F. M., Davis A. M., van Zuilen M., Hines R., and Foley C. N. 2004. Chromatographic separation and multicollection-ICPMS analysis of iron. Investigating mass-dependent and -independent isotope effects. Analytical Chemistry 76:58555863.
  • Dauphas N., Cook D. L., Sacarabany A., Fröhlich C., Davis A. M., Wadhwa M., Pourmand A., Rauscher T., and Gallino R. 2008. Iron 60 evidence for early injection and efficient mixing of stellar debris in the protosolar nebula. The Astrophysical Journal 686:560569.
  • Dauphas N., Craddock P. R., Asimow P. D., Bennett V. C., Nutman A. P., and Ohnenstetter D. 2009a. Iron isotopes may reveal the redox conditions of mantle melting from Archean to present. Earth and Planetary Science Letters 288:255267.
  • Dauphas N., Pourmand A., and Teng F.-Z. 2009b. Routine isotopic analysis of iron by HR-MC-ICPMS: How precise and how accurate? Chemical Geology 267:175184.
  • Floss C., Stadermann F. J., and Bose M. 2008. Circumstellar Fe oxide from the Acfer 094 carbonaceous chondrite. The Astrophysical Journal 672:12661271.
  • Grady M. M., Gibson E. K., Wright I. P., and Pillinger C. T. 1989. The formation of weathering products on the LEW-85320 ordinary chondrite–Evidence from carbon and oxygen stable isotope compositions and implications for carbonates in SNC meteorites. Meteoritics 24:17.
  • Hewins R. H. and Zanda B. 2012. Chondrules: Precursors and interactions with the nebular gas. Meteoritics & Planetary Science 47:11201138.
  • Hezel D. C., Needham A. W., Armytage R., Georg B., Abel R. L., Kurahashi E., Coles B. J., Rehkämper M., and Russell S. S. 2010. A nebula setting as the origin for bulk chondrule Fe isotope variations in CV chondrites. Earth and Planetary Science Letters 296:423433.
  • Hughes D. W. 1980. The dependence of chondrule density on chondrule size. Earth and Planetary Science Letters 51:2628.
  • Huss G. R., Rubin A. E., and Grossman J. N. 2006. Thermal metamorphism in chondrites. In Meteorites and the early solar system II, edited by Lauretta D. S. and McSween H. Y. Tucson, Arizona: The University of Arizona Press. pp. 567586.
  • Jones R. H. 1990. Petrology and mineralogy of type II, FeO-rich chondrules in Semarkona (LL3.0): Origin by closed-system fractional crystallization, with evidence for supercooling. Geochimica et Cosmochimica Acta 54:17851802.
  • Jones R. H. and Scott E. R. D. 1989. Petrology and thermal history of type IA chondrules in the Semarkona (LL3.0) chondrite. Proceedings, 19th Lunar and Planetary Science Conference. pp. 523536.
  • Jull A. J., Cheng S., Gooding J. L., and Velbel M. A. 1988. Rapid growth of magnesium-carbonate weathering products in a stony meteorite from Antarctica. Science 242:417419.
  • Kehm K., Hauri E. H., Alexander C. M. O'D., and Carlson R. W. 2003. High precision iron isotope measurements of meteoritic material by cold plasma ICP-MS. Geochimica et Cosmochimica Acta 67:28792891.
  • Krot A. N., Keil K., Scott E. R. D., Goodrich C. A., and Weisberg M. K. 2007. Classification of meteorites. In Meteorites, comets and planets, edited by Davis A. M. Treatise on Geochemistry, vol. 1. Oxford: Elsevier-Pergamon. pp. 152.
  • Lodders K. 2003. Solar system abundances and condensation temperatures of the elements. The Astrophysical Journal 591:12201247.
  • Lodders K. and Fegley B. 1998. The planetary scientist's companion. New York: Oxford University Press.
  • Lodders K., Palme H., and Gail H.-P. 2009. Abundances of the elements in the solar system. In Landolt-Bornstein (New Series), VI/4B ed., edited by Trumper J. E. Berlin: Springer Verlag. pp. 560630.
  • Marhas K. K., Amari S., Gyngard F., Zinner E., and Gallino R. 2008. Iron and nickel isotopic ratios in presolar SiC grains. The Astrophysical Journal 689:622645.
  • Millet M.-A., Baker J. A., and Payne C. E. 2012. Ultra-precise stable Fe isotope measurements by high resolution multiple-collector inductively coupled plasma mass spectrometry with a 57Fe–58Fe double spike. Chemical Geology 304–305:1825.
  • Mullane E., Russell S. S., and Gounelle M. 2005. Nebular and asteroidal modification of the iron isotope composition of chondritic components. Earth and Planetary Science Letters 239:203218.
  • Needham A. W., Porcelli D., and Russell S. S. 2009. An Fe isotope study of ordinary chondrites. Geochimica et Cosmochimica Acta 73:73997413.
  • Okabayashi S., Yokoyama T., and Hirata T. 2012. Iron isotopic signature for Fe-Ni metal of ordinary chondrite using newly developed technique; LAL-MC-ICPMS (abstract #1871). 43rd Lunar and Planetary Science Conference. CD-ROM.
  • Ong W. J., Floss C., and Gyngard F. 2012. Negative secondary ion measurements of 54Fe/56Fe and 57Fe/56Fe in presolar silicate grains from Acfer 094 (abstract #1864). 43rd Lunar and Planetary Science Conference. CD-ROM.
  • Poitrasson F. 2009. Probes of the ancient and the inaccessible. Science 323:882883.
  • Poitrasson F. and Freydier R. 2005. Heavy iron isotope composition of granites determined by high resolution MC-ICP-MS. Chemical Geology 222:132147.
  • Poitrasson F., Halliday A. N., Lee D. C., Levasseur S., and Teutsch N. 2004. Iron isotope differences between Earth, Moon, Mars, and Vesta as possible records of contrasted accretion mechanisms. Earth and Planetary Science Letters 223:253266.
  • Poitrasson F., Levasseur S., and Teutsch N. 2005. Significance of iron isotope mineral fractionation in pallasites and iron meteorites for the core-mantle differentiation of terrestrial planets. Earth and Planetary Science Letters 234:151164.
  • Polyakov V. B. and Mineev S. D. 2000. The use of Mossbauer spectroscopy in stable isotope geochemistry. Geochimica et Cosmochimica Acta 64:849865.
  • Polyakov V. B. and Soultanov D. M. 2011. New data on equilibrium iron isotope fractionation among sulfides: Constraints on mechanisms of sulfide formation in hydrothermal and igneous systems. Geochimica et Cosmochimica Acta 75:19571974.
  • Saunier G., Poitrasson F., Moine B., Gregoire M., and Seddiki A. 2010. Effect of hot desert weathering on the bulk-rock iron isotope composition of L6 and H5 ordinary chondrites. Meteoritics & Planetary Science 45:195209.
  • Schoenberg R. and von Blanckenburg F. 2006. Modes of planetary-scale Fe isotope fractionation. Earth and Planetary Science Letters 252:342359.
  • Scott E. R. D. and Krot A. N. 2005. Chondritic meteorites and the high-temperature nebular origins of their components. In Chondrites and the protoplanetary disk,edited by Krot A. N., Scott E. R. D., and Reipurth B. ASP Conference Series, vol. 341. San Francisco: Astronomical Society of the Pacific. pp. 1553.
  • Scott E. R. D. and Krot A. N. 2007. Chondrites and their components. In Meteorites, comets and planets, edited by Davis A. M. Treatise on Geochemistry, vol. 1. Oxford: Elsevier-Pergamon. pp. 172.
  • Theis K. J., Burgess R., Lyon I. C., and Sears D. W. 2008. The origin and history of ordinary chondrites: A study by iron isotope measurements of metal grains from ordinary chondrites. Geochimica et Cosmochimica Acta 72:44404456.
  • Velbel M., Long D., and Gooding J. 1991. Terrestrial weathering of Antarctic stone meteorites: Formation of Mg-carbonates on ordinary chondrites. Geochimica et Cosmochimica Acta 55:6776.
  • Voelkening J. and Papanastassiou D. A. 1989. Iron isotope anomalies. The Astrophysical Journal 347:L43.
  • Wang K., Moynier F., Podosek F., and Foriel J. 2011. 58Fe and 54Cr in early solar system materials. The Astrophysical Journal 739:L58.
  • Wang K., Moynier F., Dauphas N., Barrat J.-A., Craddock P., and Sio C. K. 2012a. Iron isotope fractionation in planetary crusts. Geochimica et Cosmochimica Acta 89:3145.
  • Wang K., Moynier F., Podosek F. A., and Foriel J. 2012b. An iron isotope perspective on the origin of the nanophase metallic iron in lunar regolith. Earth and Planetary Science Letters 337–338:1724.
  • Weyer S. 2008. What drives iron isotope fractionation in magma. Science 320:16001601.
  • Weyer S. and Schwieters J. B. 2003. High precision Fe isotope measurements with high mass resolution MC-ICPMS. International Journal of Mass Spectrometry 226:355368.
  • Weyer S., Anbar A. D., Brey G. P., Munker C., Mezger K., and Woodland A. B. 2005. Iron isotope fractionation during planetary differentiation. Earth and Planetary Science Letters 240:251264.
  • Wilkison S. L. and Robinson M. S. 2000. Bulk density of ordinary chondrite meteorites and implications for asteroidal internal structure. Meteoritics & Planetary Science 35:12031213.
  • Williams H. M., Markowski A., Quitte G., Halliday A. N., Teutsch N., and Levasseur S. 2006. Fe isotope fractionation in iron meteorites: New insights into metal-sulphide segregation and planetary accretion. Earth and Planetary Science Letters 250:486500.
  • Young E. D., Galy A., and Nagahara H. 2002. Kinetic and equilibrium mass-dependent isotope fractionation laws in nature and their geochemical and cosmochemical significance. Geochimica et Cosmochimica Acta 66:10951104.
  • Zanda B., Hewins R., Bourotdenise M., Bland P., and Albarede F. 2006. Formation of solar nebula reservoirs by mixing chondritic components. Earth and Planetary Science Letters 248:650660.
  • Zhu X. K., Guo Y., O'Nions R. K., Young E. D., and Ash R. D. 2001. Isotopic homogeneity of iron in the early solar nebula. Nature 412:311313.
  • Zinner E. 2007. Presolar grains. In Meteorites, comets and planets, edited by Davis A. M. Treatise on geochemistry, vol. 1. Oxford: Elsevier-Pergamon. pp. 133.