Ebel, D. S. (2006) Condensation of rocky material in astrophysical environments. In Meteorites and the Early Solar System, II, Lauretta, D. S., and McSween, H. Y., editors, pp. 253–277, University of Arizona Press, Tucson. A good summary of the modern condensation calculations and modeling of solar system processes.CrossRefGoogle Scholar

Wanke, H., and Dreibus, G. (1988) Chemical composition and accretion history of terrestrial planets. Philosophical Transactions of the Royal Society of London, A325, 545–557. This paper describes how chemical fractionations may have resulted from accretion of different materials to form the terrestrial planets.Google Scholar

Alexander, C. M. O’D., Grossman, J. N., Ebel, D. S., and Ciesla, F. J. (2008) The formation conditions of chondrules and chondrites. Science, 320, 1617–1619.Google Scholar

Alexander, C. M. O’D., Bowden, R., Fogel, M. L., and Howard, K. T. (2015) Carbonate abundances and isotopic compositions in chondrites. Meteoritics & Planetary Science, 50, 810–833.CrossRefGoogle Scholar

Asphaug, E., Agnor, C. B., and Williams, Q. (2006) Hit-and-run planetary collisions. Nature, 439, 155–160.Google Scholar

Asphaug, E., and Reufer, A. (2014) Mercury and other iron-rich planetary bodies as relicts of inefficient accretion. Nature Geoscience, 7, 564–568.CrossRefGoogle Scholar

Balta, J. B., and McSween, H. Y. (2013) Application of the MELTS algorithm to martian compositions and implications for magma crystallization. Journal of Geophysical Research, Planets, 118, 2502–2519.Google Scholar

Brearley, A. J. (2006) The action of water. In Meteorites and the Early Solar System, II, Lauretta, D. S., and McSween, H. Y., editors, pp. 587–624, University of Arizona Press, Tucson.Google Scholar

Cameron, A. G. W. (1962) The formation of the sun and planets. Icarus, 1, 13–69.Google Scholar

Campbell, A. J., Humayun, M., Meibom, A., et al. (2001) Origin of zoned metal grains in the QUE94411 chondrite. Geochimica et Cosmochimica Acta, 65, 163–180.Google Scholar

Cartier, C., and Wood, B. J. (2019) The role of reducing conditions in building Mercury. Elements, 15, 39–45.Google Scholar

Chase, M. W. (1998) NIST-JANAF Thermochemical Tables, 4th edition. American Institute of Physics, doi:10.18434/T42S31Google Scholar

Connolly, H. C., Huss, G. R., and Wasserburg, G. J. (2001) On the formation of Fe-Ni metal in CR2 meteorites. Geochimica et Cosmochimica Acta, 65, 4567–4588.Google Scholar

Davis, A. M. (2006) Volatile element evolution and loss. In Meteorites and the Early Solar System, II, Lauretta, D. S., and McSween, H. Y., editors, pp. 295–307, University of Arizona Press, Tucson.Google Scholar

Davis, A. M., and Richter, F. M. (2004) Condensation and evaporation of solar system materials. In Treatise on Geochemistry, Vol. 1: Meteorites, Comets and Planets, Davis, A. M., editor, pp. 407–430, Elsevier, Oxford.Google Scholar

Day, J. M. D., Taylor, L A., Floss, C., and McSween, H. Y. (2006) Petrology and chemistry of MIL 03346 and its significance in understanding the petrogenesis of nakhlites on Mars. Meteoritics & Planetary Science, 41, 581–606.Google Scholar

Dygert, N., Liang, Y., Sun, C., and Hess, P. (2015) Corrigendum to ‘An experimental study of trace element partitioning between augite and Fe-rich basalts.’ Geochimica et Cosmochimica Acta, 149, 281–283.CrossRefGoogle Scholar

Ebel, D. S., and Grossman, L. (2000) Condensation in dust-enriched systems. Geochimica et Cosmochimica Acta, 65, 469–477.Google Scholar

Fedo, C. M., McGlynn, I. O., and McSween, H. Y. (2015) Grain size and hydrodynamic sorting controls on the composition of basaltic sediments: Implications for interpreting martian soils. Earth & Planetary Science Letters, 423, 67–77.Google Scholar

Fegley, B. Jr. (1999) Chemical and physical processing of presolar materials in the solar nebula and the implications for preservation of presolar materials in comets. Space Science Reviews, 72, 311–326.Google Scholar

Ghiorso, M., and Sack, R. (1995) Chemical mass transfer in magmatic processes IV. A revised and internally consistent thermodynamic model for the interpolation and extrapolation of liquid-solid equilibria in magmatic systems at elevated temperatures and pressures. Contributions to Mineralogy & Petrology, 119, 197–212.Google Scholar

Grossman, L. (1972) Condensation in the primitive solar nebula. Geochimica et Cosmochimica Acta, 36, 597–619.Google Scholar

Grossman, L., and Larimer, J. W. (1974) Early chemical history of the solar system. Reviews of Geophysics & Space Physics, 12, 71–101.CrossRefGoogle Scholar

Haack, H., and McCoy, T. J. (2004) Iron and stony-iron meteorites. In Treatise on Geochemistry, Vol. 1: Meteorites, Comets and Planets, Davis, A. M., editor, pp. 325–345, Elsevier, Oxford.Google Scholar

Hurowitz, J. A., and McLennan, S. M. (2007) A ~3.5 GA record of water-limited acidic weathering conditions on Mars. Earth & Planetary Science Letters, 260, 432–443.Google Scholar

Huss, G. R. (2004) Implications of isotopic anomalies and presolar grains for the formation of the solar system. Antarctic Meteorite Research, 17, 132–152.Google Scholar

Huss, G. R., Meshik, A. P., Smith, J. B., and Hohenberg, C. M. (2003) Presolar diamond, silicon carbide, and graphite in carbonaceous chondrites: Implications for thermal processing in the solar nebula. Geochimica et Cosmochimica Acta, 67, 4823–4848.Google Scholar

Huss, G. R., Rubin, A. E., and Grossman, J. N. (2006) Thermal metamorphism in chondrites. In Meteorites and the Early Solar System, II, Lauretta, D. S., and McSween, H. Y., editors, pp. 295–307, University of Arizona Press, Tucson.Google Scholar

Jungck, M. H. A., Shimamura, T., and Lugmair, G. W. (1984) Ca isotope variations in Allende. Geochimica et Cosmochimica Acta, 48, 2651–2658.Google Scholar

Kallemeyn, G. W., and Wasson, J. T. (1981) The compositional classification of chondrites-I. The carbonaceous chondrite groups. Geochimica et Cosmochimica Acta, 45, 1217–1230.Google Scholar

Kallemeyn, G. W., Rubin, A. E., Wang, D., and Wasson, J. T. (1989) Ordinary chondrites: Bulk composition, classification, lithophile-element fractionations, and composition-petrographic type relationships. Geochimica et Cosmochimica Acta, 53, 2747–2767.Google Scholar

Kallemeyn, G. W., Rubin, A. E., and Wasson, J. T. (1994) The compositional classification of chondrites: VI. The CR carbonaceous chondrite group. Geochimica et Cosmochimica Acta, 58, 2873–2888.Google Scholar

Krähenbühl, U., Morgan, J. W., Ganapathy, R., and Anders, E. (1973) Abundances of 17 trace elements in carbonaceous chondrites. Geochimica et Cosmochimica Acta, 37, 1353–1370.Google Scholar

Kuebler, K. E., McSween, H. Y., Carlson, W. D., and Hirsch, D. (1999) Sizes and masses of chondrules and metal-troilite grains in ordinary chondrites: Possible implications for nebular sorting. Icarus, 141, 96–106,Google Scholar

Larimer, J. W., and Anders, E. (1967) Chemical fractionations in meteorites-II. Abundance patterns and their interpretation. Geochimica et Cosmochimica Acta, 31, 1239–1270.Google Scholar

Larimer, J. W., and Anders, E. (1970) Chemical fractionations in meteorites-III. Major element fractionations in chondrites. Geochimica et Cosmochimica Acta, 34, 367–387.Google Scholar

Lodders, K., and Fegley, B. (1998) The Planetary Scientist’s Companion. Oxford University Press, New York, 371 pp.Google Scholar

Longhi, J. (1991) Comparative liquidus equilibria of hypersthene-normative basalts at low pressure. American Mineralogist, 76, 785–800.Google Scholar

Longhi, J. (2006) Petrogenesis of picritic mare magmas: Constraints on the extent of early lunar differentiation. Geochimica et Cosmochimica Acta, 70, 5919–5934.Google Scholar

McCoy, T. J., Keil, K., Muenow, D. W., and Wilson, L. (1997) Partial melting and melt migration in the acopulcoite-lodranite parent body. Geochimica et Cosmochimica Acta, 61, 639–650.Google Scholar

McGlynn, I. O., Fedo, C. M., and McSween, H. Y. (2011) Origin of basaltic soils at Gusev crater, Mars, by aeolian modification of impact-generated sediment. Journal of Geophysical Research, 116, E00F22.Google Scholar

McSween, H. Y. (2015) Petrology on Mars. American Mineralogist, 100, 2380–2395.Google Scholar

McSween, H. Y., Moersch, J. E., Burr, D. M., et al. (2019) Planetary Geoscience. Cambridge University Press, Cambridge, 334 pp.Google Scholar

Niederer, F. R., Papanastassiou, D. A., and Wasserburg, G. J. (1981) The isotopic composition of titanium in the Allende and Leoville meteorites. Geochimica et Cosmochimica Acta, 45, 1017–1031.Google Scholar

Petaev, M. I., and Wood, J. A. (1998) The condensation with partial isolation (CWPI) model of condensation in the solar nebula. Meteoritics & Planetary Science, 33, 1123–1137.Google Scholar

Righter, K., Herd, C. D. K., and Boujibar, A. (2020) Redox processes in early Earth accretion and in terrestrial bodies. Elements, 16 , 161–166.Google Scholar

Rotaru, M., Birck, J. L., and Allegre, C. J. (1992) Clues to early solar-system history from chromium isotopic in carbonaceous chondrites. Nature, 358, 465–470.Google Scholar

Rushmer, T., Minarik, W. G., and Taylor, G. J. (2000) Physical processes of core formation. In Origin of the Earth and Moon, Canup, R. M., and Righter, K., editors, pp. 227–243, University of Arizona Press, Tucson.Google Scholar

Squyres, S. W., Arvidson, R. E., Ruff, S., et al. (2008) Detection of silica-rich deposits on Mars. Science, 320, 1063–1067.Google Scholar

Taylor, S. R., and McLennan, S. M. (2009) Planetary Crusts: Their Composition, Origin and Evolution. Cambridge University Press, Cambridge, 378 pp.Google Scholar

Tosca, N.J., McLennan, S. M., Clark, B. C., et al. (2005) Geochemical modeling of evaporation processes on Mars: Insight from the sedimentary record at Meridiani Planum. Earth & Planetary Science Letters, 240, 122–148.Google Scholar

Udry, A., McSween, H. Y., Lecumberri-Sanchez, P., and Bodnar, R. J. (2012) Paired nakhlites MIL 090030, 090032, 090136, and 03346: Insights into the Miller Range parent meteorite. Meteoritics & Planetary Science, 47, 1575–1589.Google Scholar

Udry, A., Gazel, E., and McSween, H. Y. (2018) Formation of evolved rocks at Gale crater by crystal fractionation and implications for Mars crustal composition. Journal of Geophysical Research, Planets, 123, doi:10.1029/2018JE005602.Google Scholar

Wade, J., and Wood, B. J. (2005) Core formation and the oxidation state of the Earth. Earth & Planetary Science Letters, 236, 78–95.Google Scholar

Wai, C. M., and Wasson, J. T. (1977) Nebular condensation of moderately volatile elements and their abundances in ordinary chondrites. Earth & Planetary Science Letters, 36, 1–13.Google Scholar

Warren, P. H. (2008) A depleted, not ideally chondritic bulk Earth: The explosive-volcanic basalt loss hypothesis. Geochimica et Cosmochimica Acta, 72, 2217–2235.CrossRefGoogle Scholar

Wasson, J. T. (1985) Meteorites. Freeman and Company, New York, 267 pp.Google Scholar

Weidenschilling, S. J. (1978) Iron/silicate fractionation and the origin of Mercury. Icarus, 35, 99–111.Google Scholar

Weiss, B. P., and Elkins-Tanton, L. T. (2013) Differentiated planetesimals and the parent bodies of chondrites. Annual Reviews of Earth & Planetary Sciences, 41, 529–560.Google Scholar

Wilson, L., and Keil, K. (1991) Consequences of explosive eruptions on small solar-system bodies – The case of the missing basalts on the aubrite parent body. Earth & Planetary Science Letters, 104, 505–512.Google Scholar

Wood, J. A., and Hashimoto, A. (1993) Mineral equilibrium in fractionated nebular systems. Geochimica et Cosmochimica Acta, 57, 2377–2388.Google Scholar

Wurm, G., Trieloff, M., and Rauer, H. (2013) Photophoretic separation of metals and silicates: The formation of Mercury-like planets and metal depletion in chondrites. Astrophysical Journal, 769, doi:10.1088/0004-637X/769/1/78.CrossRefGoogle Scholar

Yang, J., Goldstein, J. F., and Scott, E. R. D. (2007) Iron meteorite evidence for early catastrophic disruption of protoplanets. Nature, 446, 888–891.Google Scholar

Yin, Q.-Z. (2005) From dust to planets: The tale told by moderately volatile elements. In Chondrites and the Protoplanetary Disk, Krot, A. N., Scott, E. R. D., and Reipurth, B., editors, pp. 632–644, ASP Conference Series 341, Astronomical Society of the Pacific, San Francisco.Google Scholar

Yoneda, S., and Grossman, L. (1995) Condensation of CaO-MgO-Al₂O₃-SiO₂ liquids from cosmic gases. Geochimica et Cosmochimica Acta, 59, 3413–3444.Google Scholar

Alexander, C. M. O’D., Grossman, J. N., Ebel, D. S., and Ciesla, F. J. (2008) The formation conditions of chondrules and chondrites. Science, 320, 1617–1619.Google Scholar

Alexander, C. M. O’D., Bowden, R., Fogel, M. L., and Howard, K. T. (2015) Carbonate abundances and isotopic compositions in chondrites. Meteoritics & Planetary Science, 50, 810–833.CrossRefGoogle Scholar

Asphaug, E., Agnor, C. B., and Williams, Q. (2006) Hit-and-run planetary collisions. Nature, 439, 155–160.Google Scholar

Asphaug, E., and Reufer, A. (2014) Mercury and other iron-rich planetary bodies as relicts of inefficient accretion. Nature Geoscience, 7, 564–568.CrossRefGoogle Scholar

Balta, J. B., and McSween, H. Y. (2013) Application of the MELTS algorithm to martian compositions and implications for magma crystallization. Journal of Geophysical Research, Planets, 118, 2502–2519.Google Scholar

Brearley, A. J. (2006) The action of water. In Meteorites and the Early Solar System, II, Lauretta, D. S., and McSween, H. Y., editors, pp. 587–624, University of Arizona Press, Tucson.Google Scholar

Cameron, A. G. W. (1962) The formation of the sun and planets. Icarus, 1, 13–69.Google Scholar

Campbell, A. J., Humayun, M., Meibom, A., et al. (2001) Origin of zoned metal grains in the QUE94411 chondrite. Geochimica et Cosmochimica Acta, 65, 163–180.Google Scholar

Cartier, C., and Wood, B. J. (2019) The role of reducing conditions in building Mercury. Elements, 15, 39–45.Google Scholar

Chase, M. W. (1998) NIST-JANAF Thermochemical Tables, 4th edition. American Institute of Physics, doi:10.18434/T42S31Google Scholar

Connolly, H. C., Huss, G. R., and Wasserburg, G. J. (2001) On the formation of Fe-Ni metal in CR2 meteorites. Geochimica et Cosmochimica Acta, 65, 4567–4588.Google Scholar

Davis, A. M. (2006) Volatile element evolution and loss. In Meteorites and the Early Solar System, II, Lauretta, D. S., and McSween, H. Y., editors, pp. 295–307, University of Arizona Press, Tucson.Google Scholar

Davis, A. M., and Richter, F. M. (2004) Condensation and evaporation of solar system materials. In Treatise on Geochemistry, Vol. 1: Meteorites, Comets and Planets, Davis, A. M., editor, pp. 407–430, Elsevier, Oxford.Google Scholar

Day, J. M. D., Taylor, L A., Floss, C., and McSween, H. Y. (2006) Petrology and chemistry of MIL 03346 and its significance in understanding the petrogenesis of nakhlites on Mars. Meteoritics & Planetary Science, 41, 581–606.Google Scholar

Dygert, N., Liang, Y., Sun, C., and Hess, P. (2015) Corrigendum to ‘An experimental study of trace element partitioning between augite and Fe-rich basalts.’ Geochimica et Cosmochimica Acta, 149, 281–283.CrossRefGoogle Scholar

Ebel, D. S., and Grossman, L. (2000) Condensation in dust-enriched systems. Geochimica et Cosmochimica Acta, 65, 469–477.Google Scholar

Fedo, C. M., McGlynn, I. O., and McSween, H. Y. (2015) Grain size and hydrodynamic sorting controls on the composition of basaltic sediments: Implications for interpreting martian soils. Earth & Planetary Science Letters, 423, 67–77.Google Scholar

Fegley, B. Jr. (1999) Chemical and physical processing of presolar materials in the solar nebula and the implications for preservation of presolar materials in comets. Space Science Reviews, 72, 311–326.Google Scholar

Ghiorso, M., and Sack, R. (1995) Chemical mass transfer in magmatic processes IV. A revised and internally consistent thermodynamic model for the interpolation and extrapolation of liquid-solid equilibria in magmatic systems at elevated temperatures and pressures. Contributions to Mineralogy & Petrology, 119, 197–212.Google Scholar

Grossman, L. (1972) Condensation in the primitive solar nebula. Geochimica et Cosmochimica Acta, 36, 597–619.Google Scholar

Grossman, L., and Larimer, J. W. (1974) Early chemical history of the solar system. Reviews of Geophysics & Space Physics, 12, 71–101.CrossRefGoogle Scholar

Haack, H., and McCoy, T. J. (2004) Iron and stony-iron meteorites. In Treatise on Geochemistry, Vol. 1: Meteorites, Comets and Planets, Davis, A. M., editor, pp. 325–345, Elsevier, Oxford.Google Scholar

Hurowitz, J. A., and McLennan, S. M. (2007) A ~3.5 GA record of water-limited acidic weathering conditions on Mars. Earth & Planetary Science Letters, 260, 432–443.Google Scholar

Huss, G. R. (2004) Implications of isotopic anomalies and presolar grains for the formation of the solar system. Antarctic Meteorite Research, 17, 132–152.Google Scholar

Huss, G. R., Meshik, A. P., Smith, J. B., and Hohenberg, C. M. (2003) Presolar diamond, silicon carbide, and graphite in carbonaceous chondrites: Implications for thermal processing in the solar nebula. Geochimica et Cosmochimica Acta, 67, 4823–4848.Google Scholar

Huss, G. R., Rubin, A. E., and Grossman, J. N. (2006) Thermal metamorphism in chondrites. In Meteorites and the Early Solar System, II, Lauretta, D. S., and McSween, H. Y., editors, pp. 295–307, University of Arizona Press, Tucson.Google Scholar

Jungck, M. H. A., Shimamura, T., and Lugmair, G. W. (1984) Ca isotope variations in Allende. Geochimica et Cosmochimica Acta, 48, 2651–2658.Google Scholar

Kallemeyn, G. W., and Wasson, J. T. (1981) The compositional classification of chondrites-I. The carbonaceous chondrite groups. Geochimica et Cosmochimica Acta, 45, 1217–1230.Google Scholar

Kallemeyn, G. W., Rubin, A. E., Wang, D., and Wasson, J. T. (1989) Ordinary chondrites: Bulk composition, classification, lithophile-element fractionations, and composition-petrographic type relationships. Geochimica et Cosmochimica Acta, 53, 2747–2767.Google Scholar

Kallemeyn, G. W., Rubin, A. E., and Wasson, J. T. (1994) The compositional classification of chondrites: VI. The CR carbonaceous chondrite group. Geochimica et Cosmochimica Acta, 58, 2873–2888.Google Scholar

Krähenbühl, U., Morgan, J. W., Ganapathy, R., and Anders, E. (1973) Abundances of 17 trace elements in carbonaceous chondrites. Geochimica et Cosmochimica Acta, 37, 1353–1370.Google Scholar

Kuebler, K. E., McSween, H. Y., Carlson, W. D., and Hirsch, D. (1999) Sizes and masses of chondrules and metal-troilite grains in ordinary chondrites: Possible implications for nebular sorting. Icarus, 141, 96–106,Google Scholar

Larimer, J. W., and Anders, E. (1967) Chemical fractionations in meteorites-II. Abundance patterns and their interpretation. Geochimica et Cosmochimica Acta, 31, 1239–1270.Google Scholar

Larimer, J. W., and Anders, E. (1970) Chemical fractionations in meteorites-III. Major element fractionations in chondrites. Geochimica et Cosmochimica Acta, 34, 367–387.Google Scholar

Lodders, K., and Fegley, B. (1998) The Planetary Scientist’s Companion. Oxford University Press, New York, 371 pp.Google Scholar

Longhi, J. (1991) Comparative liquidus equilibria of hypersthene-normative basalts at low pressure. American Mineralogist, 76, 785–800.Google Scholar

Longhi, J. (2006) Petrogenesis of picritic mare magmas: Constraints on the extent of early lunar differentiation. Geochimica et Cosmochimica Acta, 70, 5919–5934.Google Scholar

McCoy, T. J., Keil, K., Muenow, D. W., and Wilson, L. (1997) Partial melting and melt migration in the acopulcoite-lodranite parent body. Geochimica et Cosmochimica Acta, 61, 639–650.Google Scholar

McGlynn, I. O., Fedo, C. M., and McSween, H. Y. (2011) Origin of basaltic soils at Gusev crater, Mars, by aeolian modification of impact-generated sediment. Journal of Geophysical Research, 116, E00F22.Google Scholar

McSween, H. Y. (2015) Petrology on Mars. American Mineralogist, 100, 2380–2395.Google Scholar

McSween, H. Y., Moersch, J. E., Burr, D. M., et al. (2019) Planetary Geoscience. Cambridge University Press, Cambridge, 334 pp.Google Scholar

Niederer, F. R., Papanastassiou, D. A., and Wasserburg, G. J. (1981) The isotopic composition of titanium in the Allende and Leoville meteorites. Geochimica et Cosmochimica Acta, 45, 1017–1031.Google Scholar

Petaev, M. I., and Wood, J. A. (1998) The condensation with partial isolation (CWPI) model of condensation in the solar nebula. Meteoritics & Planetary Science, 33, 1123–1137.Google Scholar

Righter, K., Herd, C. D. K., and Boujibar, A. (2020) Redox processes in early Earth accretion and in terrestrial bodies. Elements, 16 , 161–166.Google Scholar

Rotaru, M., Birck, J. L., and Allegre, C. J. (1992) Clues to early solar-system history from chromium isotopic in carbonaceous chondrites. Nature, 358, 465–470.Google Scholar

Rushmer, T., Minarik, W. G., and Taylor, G. J. (2000) Physical processes of core formation. In Origin of the Earth and Moon, Canup, R. M., and Righter, K., editors, pp. 227–243, University of Arizona Press, Tucson.Google Scholar

Squyres, S. W., Arvidson, R. E., Ruff, S., et al. (2008) Detection of silica-rich deposits on Mars. Science, 320, 1063–1067.Google Scholar

Taylor, S. R., and McLennan, S. M. (2009) Planetary Crusts: Their Composition, Origin and Evolution. Cambridge University Press, Cambridge, 378 pp.Google Scholar

Tosca, N.J., McLennan, S. M., Clark, B. C., et al. (2005) Geochemical modeling of evaporation processes on Mars: Insight from the sedimentary record at Meridiani Planum. Earth & Planetary Science Letters, 240, 122–148.Google Scholar

Udry, A., McSween, H. Y., Lecumberri-Sanchez, P., and Bodnar, R. J. (2012) Paired nakhlites MIL 090030, 090032, 090136, and 03346: Insights into the Miller Range parent meteorite. Meteoritics & Planetary Science, 47, 1575–1589.Google Scholar

Udry, A., Gazel, E., and McSween, H. Y. (2018) Formation of evolved rocks at Gale crater by crystal fractionation and implications for Mars crustal composition. Journal of Geophysical Research, Planets, 123, doi:10.1029/2018JE005602.Google Scholar

Wade, J., and Wood, B. J. (2005) Core formation and the oxidation state of the Earth. Earth & Planetary Science Letters, 236, 78–95.Google Scholar

Wai, C. M., and Wasson, J. T. (1977) Nebular condensation of moderately volatile elements and their abundances in ordinary chondrites. Earth & Planetary Science Letters, 36, 1–13.Google Scholar

Warren, P. H. (2008) A depleted, not ideally chondritic bulk Earth: The explosive-volcanic basalt loss hypothesis. Geochimica et Cosmochimica Acta, 72, 2217–2235.CrossRefGoogle Scholar

Wasson, J. T. (1985) Meteorites. Freeman and Company, New York, 267 pp.Google Scholar

Weidenschilling, S. J. (1978) Iron/silicate fractionation and the origin of Mercury. Icarus, 35, 99–111.Google Scholar

Weiss, B. P., and Elkins-Tanton, L. T. (2013) Differentiated planetesimals and the parent bodies of chondrites. Annual Reviews of Earth & Planetary Sciences, 41, 529–560.Google Scholar

Wilson, L., and Keil, K. (1991) Consequences of explosive eruptions on small solar-system bodies – The case of the missing basalts on the aubrite parent body. Earth & Planetary Science Letters, 104, 505–512.Google Scholar

Wood, J. A., and Hashimoto, A. (1993) Mineral equilibrium in fractionated nebular systems. Geochimica et Cosmochimica Acta, 57, 2377–2388.Google Scholar

Wurm, G., Trieloff, M., and Rauer, H. (2013) Photophoretic separation of metals and silicates: The formation of Mercury-like planets and metal depletion in chondrites. Astrophysical Journal, 769, doi:10.1088/0004-637X/769/1/78.CrossRefGoogle Scholar

Yang, J., Goldstein, J. F., and Scott, E. R. D. (2007) Iron meteorite evidence for early catastrophic disruption of protoplanets. Nature, 446, 888–891.Google Scholar

Yin, Q.-Z. (2005) From dust to planets: The tale told by moderately volatile elements. In Chondrites and the Protoplanetary Disk, Krot, A. N., Scott, E. R. D., and Reipurth, B., editors, pp. 632–644, ASP Conference Series 341, Astronomical Society of the Pacific, San Francisco.Google Scholar

Yoneda, S., and Grossman, L. (1995) Condensation of CaO-MgO-Al₂O₃-SiO₂ liquids from cosmic gases. Geochimica et Cosmochimica Acta, 59, 3413–3444.Google Scholar

Alexander, C. M. O’D., Grossman, J. N., Ebel, D. S., and Ciesla, F. J. (2008) The formation conditions of chondrules and chondrites. Science, 320, 1617–1619.Google Scholar

Alexander, C. M. O’D., Bowden, R., Fogel, M. L., and Howard, K. T. (2015) Carbonate abundances and isotopic compositions in chondrites. Meteoritics & Planetary Science, 50, 810–833.CrossRefGoogle Scholar

Asphaug, E., Agnor, C. B., and Williams, Q. (2006) Hit-and-run planetary collisions. Nature, 439, 155–160.Google Scholar

Asphaug, E., and Reufer, A. (2014) Mercury and other iron-rich planetary bodies as relicts of inefficient accretion. Nature Geoscience, 7, 564–568.CrossRefGoogle Scholar

Balta, J. B., and McSween, H. Y. (2013) Application of the MELTS algorithm to martian compositions and implications for magma crystallization. Journal of Geophysical Research, Planets, 118, 2502–2519.Google Scholar

Brearley, A. J. (2006) The action of water. In Meteorites and the Early Solar System, II, Lauretta, D. S., and McSween, H. Y., editors, pp. 587–624, University of Arizona Press, Tucson.Google Scholar

Cameron, A. G. W. (1962) The formation of the sun and planets. Icarus, 1, 13–69.Google Scholar

Campbell, A. J., Humayun, M., Meibom, A., et al. (2001) Origin of zoned metal grains in the QUE94411 chondrite. Geochimica et Cosmochimica Acta, 65, 163–180.Google Scholar

Cartier, C., and Wood, B. J. (2019) The role of reducing conditions in building Mercury. Elements, 15, 39–45.Google Scholar

Chase, M. W. (1998) NIST-JANAF Thermochemical Tables, 4th edition. American Institute of Physics, doi:10.18434/T42S31Google Scholar

Connolly, H. C., Huss, G. R., and Wasserburg, G. J. (2001) On the formation of Fe-Ni metal in CR2 meteorites. Geochimica et Cosmochimica Acta, 65, 4567–4588.Google Scholar

Davis, A. M. (2006) Volatile element evolution and loss. In Meteorites and the Early Solar System, II, Lauretta, D. S., and McSween, H. Y., editors, pp. 295–307, University of Arizona Press, Tucson.Google Scholar

Davis, A. M., and Richter, F. M. (2004) Condensation and evaporation of solar system materials. In Treatise on Geochemistry, Vol. 1: Meteorites, Comets and Planets, Davis, A. M., editor, pp. 407–430, Elsevier, Oxford.Google Scholar

Day, J. M. D., Taylor, L A., Floss, C., and McSween, H. Y. (2006) Petrology and chemistry of MIL 03346 and its significance in understanding the petrogenesis of nakhlites on Mars. Meteoritics & Planetary Science, 41, 581–606.Google Scholar

Dygert, N., Liang, Y., Sun, C., and Hess, P. (2015) Corrigendum to ‘An experimental study of trace element partitioning between augite and Fe-rich basalts.’ Geochimica et Cosmochimica Acta, 149, 281–283.CrossRefGoogle Scholar

Ebel, D. S., and Grossman, L. (2000) Condensation in dust-enriched systems. Geochimica et Cosmochimica Acta, 65, 469–477.Google Scholar

Fedo, C. M., McGlynn, I. O., and McSween, H. Y. (2015) Grain size and hydrodynamic sorting controls on the composition of basaltic sediments: Implications for interpreting martian soils. Earth & Planetary Science Letters, 423, 67–77.Google Scholar

Fegley, B. Jr. (1999) Chemical and physical processing of presolar materials in the solar nebula and the implications for preservation of presolar materials in comets. Space Science Reviews, 72, 311–326.Google Scholar

Ghiorso, M., and Sack, R. (1995) Chemical mass transfer in magmatic processes IV. A revised and internally consistent thermodynamic model for the interpolation and extrapolation of liquid-solid equilibria in magmatic systems at elevated temperatures and pressures. Contributions to Mineralogy & Petrology, 119, 197–212.Google Scholar

Grossman, L. (1972) Condensation in the primitive solar nebula. Geochimica et Cosmochimica Acta, 36, 597–619.Google Scholar

Grossman, L., and Larimer, J. W. (1974) Early chemical history of the solar system. Reviews of Geophysics & Space Physics, 12, 71–101.CrossRefGoogle Scholar

Haack, H., and McCoy, T. J. (2004) Iron and stony-iron meteorites. In Treatise on Geochemistry, Vol. 1: Meteorites, Comets and Planets, Davis, A. M., editor, pp. 325–345, Elsevier, Oxford.Google Scholar

Hurowitz, J. A., and McLennan, S. M. (2007) A ~3.5 GA record of water-limited acidic weathering conditions on Mars. Earth & Planetary Science Letters, 260, 432–443.Google Scholar

Huss, G. R. (2004) Implications of isotopic anomalies and presolar grains for the formation of the solar system. Antarctic Meteorite Research, 17, 132–152.Google Scholar

Huss, G. R., Meshik, A. P., Smith, J. B., and Hohenberg, C. M. (2003) Presolar diamond, silicon carbide, and graphite in carbonaceous chondrites: Implications for thermal processing in the solar nebula. Geochimica et Cosmochimica Acta, 67, 4823–4848.Google Scholar

Huss, G. R., Rubin, A. E., and Grossman, J. N. (2006) Thermal metamorphism in chondrites. In Meteorites and the Early Solar System, II, Lauretta, D. S., and McSween, H. Y., editors, pp. 295–307, University of Arizona Press, Tucson.Google Scholar

Jungck, M. H. A., Shimamura, T., and Lugmair, G. W. (1984) Ca isotope variations in Allende. Geochimica et Cosmochimica Acta, 48, 2651–2658.Google Scholar

Kallemeyn, G. W., and Wasson, J. T. (1981) The compositional classification of chondrites-I. The carbonaceous chondrite groups. Geochimica et Cosmochimica Acta, 45, 1217–1230.Google Scholar

Kallemeyn, G. W., Rubin, A. E., Wang, D., and Wasson, J. T. (1989) Ordinary chondrites: Bulk composition, classification, lithophile-element fractionations, and composition-petrographic type relationships. Geochimica et Cosmochimica Acta, 53, 2747–2767.Google Scholar

Kallemeyn, G. W., Rubin, A. E., and Wasson, J. T. (1994) The compositional classification of chondrites: VI. The CR carbonaceous chondrite group. Geochimica et Cosmochimica Acta, 58, 2873–2888.Google Scholar

Krähenbühl, U., Morgan, J. W., Ganapathy, R., and Anders, E. (1973) Abundances of 17 trace elements in carbonaceous chondrites. Geochimica et Cosmochimica Acta, 37, 1353–1370.Google Scholar

Kuebler, K. E., McSween, H. Y., Carlson, W. D., and Hirsch, D. (1999) Sizes and masses of chondrules and metal-troilite grains in ordinary chondrites: Possible implications for nebular sorting. Icarus, 141, 96–106,Google Scholar

Larimer, J. W., and Anders, E. (1967) Chemical fractionations in meteorites-II. Abundance patterns and their interpretation. Geochimica et Cosmochimica Acta, 31, 1239–1270.Google Scholar

Larimer, J. W., and Anders, E. (1970) Chemical fractionations in meteorites-III. Major element fractionations in chondrites. Geochimica et Cosmochimica Acta, 34, 367–387.Google Scholar

Lodders, K., and Fegley, B. (1998) The Planetary Scientist’s Companion. Oxford University Press, New York, 371 pp.Google Scholar

Longhi, J. (1991) Comparative liquidus equilibria of hypersthene-normative basalts at low pressure. American Mineralogist, 76, 785–800.Google Scholar

Longhi, J. (2006) Petrogenesis of picritic mare magmas: Constraints on the extent of early lunar differentiation. Geochimica et Cosmochimica Acta, 70, 5919–5934.Google Scholar

McCoy, T. J., Keil, K., Muenow, D. W., and Wilson, L. (1997) Partial melting and melt migration in the acopulcoite-lodranite parent body. Geochimica et Cosmochimica Acta, 61, 639–650.Google Scholar

McGlynn, I. O., Fedo, C. M., and McSween, H. Y. (2011) Origin of basaltic soils at Gusev crater, Mars, by aeolian modification of impact-generated sediment. Journal of Geophysical Research, 116, E00F22.Google Scholar

McSween, H. Y. (2015) Petrology on Mars. American Mineralogist, 100, 2380–2395.Google Scholar

McSween, H. Y., Moersch, J. E., Burr, D. M., et al. (2019) Planetary Geoscience. Cambridge University Press, Cambridge, 334 pp.Google Scholar

Niederer, F. R., Papanastassiou, D. A., and Wasserburg, G. J. (1981) The isotopic composition of titanium in the Allende and Leoville meteorites. Geochimica et Cosmochimica Acta, 45, 1017–1031.Google Scholar

Petaev, M. I., and Wood, J. A. (1998) The condensation with partial isolation (CWPI) model of condensation in the solar nebula. Meteoritics & Planetary Science, 33, 1123–1137.Google Scholar

Righter, K., Herd, C. D. K., and Boujibar, A. (2020) Redox processes in early Earth accretion and in terrestrial bodies. Elements, 16 , 161–166.Google Scholar

Rotaru, M., Birck, J. L., and Allegre, C. J. (1992) Clues to early solar-system history from chromium isotopic in carbonaceous chondrites. Nature, 358, 465–470.Google Scholar

Rushmer, T., Minarik, W. G., and Taylor, G. J. (2000) Physical processes of core formation. In Origin of the Earth and Moon, Canup, R. M., and Righter, K., editors, pp. 227–243, University of Arizona Press, Tucson.Google Scholar

Squyres, S. W., Arvidson, R. E., Ruff, S., et al. (2008) Detection of silica-rich deposits on Mars. Science, 320, 1063–1067.Google Scholar

Taylor, S. R., and McLennan, S. M. (2009) Planetary Crusts: Their Composition, Origin and Evolution. Cambridge University Press, Cambridge, 378 pp.Google Scholar

Tosca, N.J., McLennan, S. M., Clark, B. C., et al. (2005) Geochemical modeling of evaporation processes on Mars: Insight from the sedimentary record at Meridiani Planum. Earth & Planetary Science Letters, 240, 122–148.Google Scholar

Udry, A., McSween, H. Y., Lecumberri-Sanchez, P., and Bodnar, R. J. (2012) Paired nakhlites MIL 090030, 090032, 090136, and 03346: Insights into the Miller Range parent meteorite. Meteoritics & Planetary Science, 47, 1575–1589.Google Scholar

Udry, A., Gazel, E., and McSween, H. Y. (2018) Formation of evolved rocks at Gale crater by crystal fractionation and implications for Mars crustal composition. Journal of Geophysical Research, Planets, 123, doi:10.1029/2018JE005602.Google Scholar

Wade, J., and Wood, B. J. (2005) Core formation and the oxidation state of the Earth. Earth & Planetary Science Letters, 236, 78–95.Google Scholar

Wai, C. M., and Wasson, J. T. (1977) Nebular condensation of moderately volatile elements and their abundances in ordinary chondrites. Earth & Planetary Science Letters, 36, 1–13.Google Scholar

Warren, P. H. (2008) A depleted, not ideally chondritic bulk Earth: The explosive-volcanic basalt loss hypothesis. Geochimica et Cosmochimica Acta, 72, 2217–2235.CrossRefGoogle Scholar

Wasson, J. T. (1985) Meteorites. Freeman and Company, New York, 267 pp.Google Scholar

Weidenschilling, S. J. (1978) Iron/silicate fractionation and the origin of Mercury. Icarus, 35, 99–111.Google Scholar

Weiss, B. P., and Elkins-Tanton, L. T. (2013) Differentiated planetesimals and the parent bodies of chondrites. Annual Reviews of Earth & Planetary Sciences, 41, 529–560.Google Scholar

Wilson, L., and Keil, K. (1991) Consequences of explosive eruptions on small solar-system bodies – The case of the missing basalts on the aubrite parent body. Earth & Planetary Science Letters, 104, 505–512.Google Scholar

Wood, J. A., and Hashimoto, A. (1993) Mineral equilibrium in fractionated nebular systems. Geochimica et Cosmochimica Acta, 57, 2377–2388.Google Scholar

Wurm, G., Trieloff, M., and Rauer, H. (2013) Photophoretic separation of metals and silicates: The formation of Mercury-like planets and metal depletion in chondrites. Astrophysical Journal, 769, doi:10.1088/0004-637X/769/1/78.CrossRefGoogle Scholar

Yang, J., Goldstein, J. F., and Scott, E. R. D. (2007) Iron meteorite evidence for early catastrophic disruption of protoplanets. Nature, 446, 888–891.Google Scholar

Yin, Q.-Z. (2005) From dust to planets: The tale told by moderately volatile elements. In Chondrites and the Protoplanetary Disk, Krot, A. N., Scott, E. R. D., and Reipurth, B., editors, pp. 632–644, ASP Conference Series 341, Astronomical Society of the Pacific, San Francisco.Google Scholar

Yoneda, S., and Grossman, L. (1995) Condensation of CaO-MgO-Al₂O₃-SiO₂ liquids from cosmic gases. Geochimica et Cosmochimica Acta, 59, 3413–3444.Google Scholar