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References

  • Anders E. and Grevesse N. 1989. Abundances of the elements: Meteoritic and solar. Geochimica et Cosmochimica Acta 53:197214.
  • Asimow P. D. and Longhi J. 2004. The significance of multiple saturation points in the context of polybaric near-fractional melting. Journal of Petrology 45:23492367.
  • Banin A., Clark B. C., and Wänke H. 1992. Surface chemistry and mineralogy. In Mars, edited by Kieffer H. H., Jakosky B. M., Snyder C. W., and Matthews M. S. Tuscon, Arizona: The University of Arizona Press. pp. 594625.
  • Barrat J. A., Blichert-Toft J., Nesbitt R. W., and Keller F. 2001. Bulk chemistry of Saharan shergottite Dar al Gani 476. Meteoritics & Planetary Science 36:2329.
  • Barrat J. A., Gillet P., Sautter V., Jambon A., Javoy M., Göpel C., Lesourd M., Keller F., and Petit E. 2002a. Petrology and chemistry of the basaltic shergottite Northwest Africa 480. Meteoritics & Planetary Science 37:487499.
  • Barrat J. A., Jambon A., Bohn M., Gillet P., Sautter V., Göpel C., Lesourd M., and Keller F. 2002b. Petrology and chemistry of the picritic shergottite Northwest Africa 1068 (NWA 1068). Geochimica et Cosmochimica Acta 66:35053518.
  • Basu Sarbadhikari A., Day J. M. D., Liu Y., Rumble D., III, and Taylor L. A. 2009. Petrogenesis of olivine-phyric shergottite Larkman Nunatak 06319: Implications for enriched components in Martian basalts. Geochimica et Cosmochimica Acta 73:21902214.
  • Basu Sarbadhikari A., Goodrich C. A., Liu Y., Day J. M. D., and Taylor L. A. 2011. Evidence for heterogeneous enriched shergottite mantle sources in Mars from olivine-hosted melt inclusions in Larkman Nunatak 06319. Geochimica et Cosmochimica Acta 75:68036820.
  • Borg L. E. and Draper D. S. 2003. A petrogenetic model for the origin and compositional variation of the Martian basaltic meteorites. Meteoritics & Planetary Science 38:17131731.
  • Brandon A. D., Puchtel I. S., Walker R. J., Day J. M. D., Irving A., and Taylor L. A. 2012. Evolution of the Martian mantle inferred from the 187Re-187Os isotope and highly siderophile element abundance systematics of shergottite meteorites. Geochimica et Cosmochimica Acta 76:206235.
  • Bridges J. C. and Warren P. H. 2006. The SNC meteorites: Basaltic igneous processes on Mars. Journal of the Geological Society 163:229251.
  • Brooker R. A., James R. H., and Blundy J. D. 2004. Trace elements and Li isotope systematics in Zabargad peridotites: Evidence of ancient subduction processes in the Red Sea mantle. Chemical Geology 212:179204.
  • Bunch T., Irving A., Wittke J., Rumble D., Korotev R., Gellissen M., and Palme H. 2009. Petrology and composition of Northwest Africa 2990: A new type of fine-grained, enriched, olivine-phyric shergottite (abstract #2274). 40th Lunar and Planetary Science Conference. CD-ROM.
  • Burghele A., Dreibus G., Palme H., Rammensee W., Spettel B., Weckwerth G., and Wänke H. 1983. Chemistry of shergottites and the shergotty parent body (SPB): Further evidence for the two component model of planet formation. Proceedings, 14th Lunar and Planetary Science Conference. pp. 8081.
  • Clayton R. N. 2003. Oxygen isotopes in the solar system. Space Science Reviews 106:1932.
  • Clayton R. N. and Mayeda T. K. 1996. Oxygen isotope studies of achondrites. Geochimica et Cosmochimica Acta 60:19992017.
  • Cornish L. and Doyle A. 1984. Use of ethanolamine thioglycollate in the conservation of pyritized fossils. Palaeontology 27:421424.
  • Crozaz G., Floss C., and Wadhwa M. 2003. Chemical alteration and REE mobilization in meteorites from hot and cold deserts. Geochimica et Cosmochimica Acta 67:47274741.
  • Day J. M. D., Taylor L. A., Valley J. W., and Spicuzzi M. J. 2005. Assimilation of high 18O/16O crust by Shergottite-Nakhlite-Chassigny (SNC) magmas on Mars. EOS, Transactions of the American Geophysical Union 86(52), Fall Meet. Suppl., Abstract P51A-0902.
  • Day J. M. D., Pearson D. G., Macpherson C. G., Lowry D., and Carracedo J. C. 2010a. Evidence for distinct proportions of subducted oceanic crust and lithosphere in HIMU-type mantle beneath El Hierro and La Palma, Canary Islands. Geochimica et Cosmochimica Acta 74:65656589.
  • Day J. M. D., Walker R. J., James O. B., and Puchtel I. S. 2010b. Osmium isotope and highly siderophile element systematics of the lunar crust. Earth and Planetary Science Letters 289:595605.
  • Dreibus G. and Wänke H. 1982. Parent body of the SNC-meteorites: Chemistry, size and formation. Meteoritics 17:207208.
  • Dreibus G. and Wänke H. 1985. Mars, a volatile-rich planet. Meteoritics 20:367381.
  • Dreibus G. and Wänke H. 1987. Volatiles on Earth and Mars—A comparison. Icarus 71:225240.
  • Dreibus G., Spettel B., Wlotzka F., Schultz L., Weber H. W., Jochum K. P., and Wanke H. 1996. QUE 94201: An unusual Martian basalt. Meteoritics & Planetary Science 31:A39A40.
  • Dreibus G., Spettel B., Haubold R., Jochum K. P., Palme H., Wolf D., and Zipfel J. 2000. Chemistry of a new shergottite: Sayh al Uhaymir 005. Meteoritics & Planetary Science 35:A49.
  • Dreibus G., Haubold R., Huisl W., and Spettel B. 2003. Comparison of the chemistry of Yamato 980459 with DaG 476 and SaU 005. International Symposium, Evolution of Solar System Materials: A New Perspective from Antarctic Meteorites. Tokyo: National Institute of Polar Research. pp. 19–20.
  • Duke M. B. 1968. The Shergotty meteorite: Magmatic and shock metamorphic features. In Shock metamorphism of natural materials, Baltimore, Maryland: Mono Book Corp. pp. 612621.
  • Easton A. J. and Elliott C. J. 1977. Analyses of some meteorites from the British Museum/Natural History collection. Meteoritics 12:409416.
  • Filiberto J. 2008. Similarities between the shergottites and terrestrial ferropicrites. Icarus 197:5259.
  • Filiberto J. 2011. Geochemical differences between surface basalts and Martian meteorites: The need for Martian sample return (abstract #5004). Workshop, Solar System Sample Return Mission.
  • Filiberto J., and Dasgupta R. 2011. Fe2+-Mg partitioning between olivine and basaltic melts: Applications to genesis of olivine-phyric shergottites and conditions of melting in the Martian interior. Earth and Planetary Science Letters 304:527537.
  • Filiberto J., Nekvasil H., and Lindsley D. H. 2006. The Mars/Earth dichotomy in Mg/Si and Al/Si ratios: Is it real? American Mineralogist 91:471474.
  • Filiberto J., Treiman A. H., and Le L. 2008. Crystallization experiments on a Gusev Adirondack basalt composition. Meteoritics & Planetary Science 43:11371146.
  • Filiberto J., Jackson C., Le L., and Treiman A. H. 2009. Partitioning of Ni between olivine and an iron-rich basalt: Experiments, partition models, and planetary implications. American Mineralogist 94:256261.
  • Filiberto J., Dasgupta R., Kiefer W. S., and Treiman A. H. 2010a. High pressure, near-liquidus phase equilibria of the Home Plate basalt Fastball and melting in the Martian mantle. Geophysical Research Letters 37, L13201, doi:13210.11029/12010GL043999.
  • Filiberto J., Musselwhite D. S., Gross J., Burgess K., Le L., and Treiman A. H. 2010b. Experimental petrology, crystallization history, and parental magma characteristics of olivine-phyric shergottite NWA 1068: Implications for the petrogenesis of “enriched” olivine-phyric shergottites. Meteoritics & Planetary Science 45:12581270.
  • Filiberto J., Abernethy F., Butler I. B., Cartwright J., Chin E. J., Day J. M. D., Goodrich C., Grady M., Gross J., Franchi I. A., Herd C. D. K., Kelley S. P., Ott U., Penniston-Dorland S., Schwenzer S. P., and Treiman A. H. 2011. Maximizing the science return from 3.3 g of Martian meteorite: A consortium study of olivine-phyric shergottite Northwest Africa 6234. EOS, Meteoritics & Planetary Science 46(Suppl.):A108.
  • Flesch G. D., Anderson A. R., Jr., and Svec H. J. 1973. A secondary isotopic standard for 6Li/7Li determinations. International Journal of Mass Spectrometry and Ion Physics 12:265272.
  • Folco L., Franchi I. A., D’Orazio M., Rocchi S., and Schultz L. 2000. A new Martian meteorite from the Sahara: The shergottite Dar al Gani 489. Meteoritics & Planetary Science 35:827839.
  • Franchi I. A., Wright I. P., Sexton A. S., and Pillinger C. T. 1999. The oxygen-isotopic composition of Earth and Mars. Meteoritics & Planetary Science 34:657661.
  • Gnos E., Hofmann B., Franchi I. A., Al-Kathiri A., Huser M., and Moser L. 2002. Sayh al Uhaymir 094: A new Martian meteorite from the Oman Desert. Meteoritics & Planetary Science 37:835854.
  • Goodrich C. A. 2002. Olivine-phyric Martian basalts: A new type of shergottite. Meteoritics & Planetary Science 37:3134.
  • Goodrich C. A. 2003. Petrogenesis of olivine-phyric shergottites Sayh al Uhaymir 005 and Elephant Moraine A79001 lithology A. Geochimica et Cosmochimica Acta 67:37353772.
  • Greshake A., Fritz J., and Stöffler D. 2004. Petrology and shock metamorphism of the olivine-phyric shergottite Yamato 980459: Evidence for a two-stage cooling and a single-stage ejection history. Geochimica et Cosmochimica Acta 68:23592377.
  • Gross J., Treiman A. H., Filiberto J., and Herd C. D. K. 2011. Primitive olivine-phyric shergottite NWA 5789: Petrography, mineral chemistry, and cooling history imply a magma similar to Yamato-980459. Meteoritics & Planetary Science 46:116133.
  • Gross J., Filiberto J., Treiman A., Herd C. D. K., Melwani Daswani M., and Schwenzer S. P. 2012. Petrography, mineral chemistry, and crystallization history of Olivine-Phyric Shergottite NWA 6234: A new intermediate melt composition (abstract #2693). 43rd Lunar and Planetary Science Conference. CD-ROM.
  • Herd C. D. K., Dwarzski R. E., and Shearer C. K. 2009. The behavior of Co and Ni in olivine in planetary basalts: An experimental investigation. American Mineralogist 94:244255.
  • Horan M. F., Walker R. J., Morgan J. W., Grossman J. N., and Rubin A. E. 2003. Highly siderophile elements in chondrites. Chemical Geology 196:2742.
  • Ikeda Y. 1998. Petrology of magmatic silicate inclusions in the Allan Hills 77005 lherzolitic shergottite. Meteoritics & Planetary Science 33:803812.
  • Ikeda Y. and Shimoda G. 2005. Major-element trend for shergottite melts and their source materials. Antarctic Meteorite Research 18:152169.
  • Ikeda Y., Kimura M., Takeda H., Shimoda G., Kita N. T., Morishita Y., Suzuki A., Jagoutz E., and Dreibus G. 2006. Petrology of a new basaltic shergottite: Dhofar 378. Antarctic Meteorite Research 19:2044.
  • Irving A., Kuehner S., Herd C., Gellissen M., Korotev R., Puchtel I., Walker R., Lapen T., and Rumble D. 2010. Petrologic, elemental and multi-isotopic characterization of permafic olivine-phyric shergottite Northwest Africa 5789: A primitive magma derived from depleted Martian mantle (abstract #1547). 41st Lunar and Planetary Science Conference. CD-ROM.
  • Irving A., Herd C., Gellissen M., Kuehner S., and Bunch T. 2011. Paired fine grained, permafic olivine-phyric shergottites northwest Africa 2990/5960/6234/6710: Trace element evidence for a new type of Martian mantle source or complex lithospheric assimilation processes (abstract #5232). Meteoritics 46(S1):A108.
  • Jambon A., Barrat J. A., Sautter V., Gillet P., Göpel C., Javoy M., Joron J. L., and Lesourd M. 2002. The basaltic shergottite Northwest Africa 856 (NWA 856): Petrology and chemistry. Meteoritics & Planetary Science 37:11471164.
  • Jeffcoate A. B., Elliott T., Kasemann S. A., Ionov D., Cooper K., and Brooker R. 2007. Li isotope fractionation in peridotites and mafic melts. Geochimica et Cosmochimica Acta 71:202218.
  • Jérome D. Y. 1970. Composition and origin of some achondrite meteorites. Eugene, Oregon: University of Oregon. 166 p.
  • Jones J. 2003. Constraints on the structure of the Martian interior determined from the chemical and isotopic systematics of SNC meteorites. Meteoritics & Planetary Science 38:18071814.
  • Karner J., Papike J. J., and Shearer C. K. 2003. Olivine from planetary basalts: Chemical signatures that indicate planetary parentage and those that record igneous setting and process. American Mineralogist 88:806816.
  • Karner J., Papike J. J., and Shearer C. K. 2004. Plagioclase from planetary basalts: Chemical signatures that reflect planetary volatile budgets, oxygen fugacity, and styles of igneous differentiation. American Mineralogist 89:11011109.
  • Koizumi E., McKay G., Mikouchi T., Le L., Schwandt C., Monkawa A., and Miyamoto M. 2002. Crystallization experiments of the Martian meteorite QUE94201: Additional constraints on its formation condition (abstract #1442). 33rd Lunar and Planetary Science Conference. CD-ROM.
  • Kong P., Ebihara M., and Palme H. 1999. Siderophile elements in Martian meteorites and implications for core formation in Mars. Geochimica et Cosmochimica Acta 63:18651875.
  • Kring D. A., Gleason J. D., Hill D. H., Jull A. J. T., and Boynton W. V. 1996. QUE 94201, a new Martian meteorite that may represent a bulk melt rather than a cumulate fraction (abstract). 27th Lunar and Planetary Science Conference. p. 705.
  • Kring D. A., Gleason J. D., Swindle T. D., Nishiizumi K., Caffee M. W., Hill D. H., Jull A. J. T., and Boynton W. V. 2003. Composition of the first bulk melt sample from a volcanic region of Mars: Queen Alexandra range 94201. Meteoritics & Planetary Science 38:18331848.
  • Lapen T. J., Righter M., Brandon A. D., Beard B. L., Shafer J., and Irving A. 2009. Lu-Hf isotope systematics of NWA 4468 and NWA 2990: Implications for the sources of shergottites. 40th Lunar and Planetary Science Conference. CD-ROM.
  • Laul J. C. 1987. Rare Earth patterns in shergottite phosphates and residues. Journal of Geophysical Research 92:E633E640.
  • Laul J. C., Smith M. R., Wänke H., Jagoutz E., Dreibus G., Palme H., Spettel B., Burghele A., Lipschutz M. E., and Verkouteren R. M. 1986. Chemical systematics of the shergotty meteorite and the composition of its parent body (Mars). Geochimica et Cosmochimica Acta 50:909926.
  • Lee C.-T. A., Oka M., Luffi P., and Agranier A. 2008. Internal distribution of Li and B in serpentinites from the Feather River Ophiolite, California, based on laser ablation inductively coupled plasma mass spectrometry. Geochemistry Geophysics Geosystems 9:Q12011.
  • Lin Y., Guan Y., Wang A., Kimura M., and Leshin L. A. 2005. Petrogenesis of the new lherzolitic shergottite Grove Mountains 99027: Constraints of petrography, mineral chemistry, and rare earth elements. Meteoritics & Planetary Science 40:15991619.
  • Lodders K. 1998. A survey of shergottite, nakhlite and chassigny meteorites whole-rock compositions. Meteoritics & Planetary Science 33:A183A190.
  • Longhi J. 1991. Complex magmatic processes on Mars—Inferences from the SNC meteorites. Proceedings, 21st Lunar and Planetary Science Conference. pp. 695709.
  • Longhi J., Durand S. R., and Walker D. 2010. The pattern of Ni and Co abundances in lunar olivines. Geochimica et Cosmochimica Acta 74:784798.
  • Ma M. S., Laul J., Smith M., and Schmitt R. 1982. Chemistry of the shergottites Elephant Moraine A79001 and Zagami. Proceedings, 13th Lunar and Planetary Science Conference. pp. 451452.
  • Magna T., Wiechert U., Grove T. L., and Halliday A. N. 2006a. Lithium isotope fractionation in the southern Cascadia subduction zone. Earth and Planetary Science Letters 250:428443.
  • Magna T., Wiechert U., and Halliday A. N. 2006b. New constraints on the lithium isotope compositions of the Moon and terrestrial planets. Earth and Planetary Science Letters 243:336353.
  • Martins Z., Hofmann B. A., Gnos E., Greenwood R. C., Verchovsky A., Franchi I. A., Jull A. J. T., Botta O., Glavin D. P., Dworkin J. P., and Ehrenfreund P. 2007. Amino acid composition, petrology, geochemistry, 14C terrestrial age and oxygen isotopes of the Shişr 033 CR chondrite. Meteoritics & Planetary Science 42:15811595.
  • McCarthy T. S., Erlank A. J., Willis J. P., and Ahrens L. H. 1974. New chemical analyses of six achondrites and one chondrite. Meteoritics 9:215222.
  • McLennan S. M. 2003. Large-ion lithophile element fractionation during the early differentiation of Mars and the composition of the Martian primitive mantle. Meteoritics & Planetary Science 38:895904.
  • McSween H. Y. 1985. SNC meteorites: Clues to Martian petrologic evolution? Reviews of Geophysics 23:391416.
  • McSween H. Y. 1994. What we have learned about Mars from SNC meteorites. Meteoritics 29:757779.
  • McSween H. Y. 2002. The rocks of Mars, from far and near. Meteoritics & Planetary Science 37:725.
  • McSween H. Y. and Jarosewich E. 1983. Petrogenesis of the Elephant Moraine A79001 Meteorite—Multiple magma pulses on the Shergottite parent body. Geochimica et Cosmochimica Acta 47:15011513.
  • McSween H. Y. and Treiman A. H. 1998. Martian meteorites. In Planetary materials, edited by Papike J. J. Reviews in Mineralogy, vol. 36. Reston, VA: Mineralogical Society of America. pp. 6-01-06-40.
  • McSween H. Y., Taylor G. J., and Wyatt M. B. 2009. Elemental composition of the Martian crust. Science 324:736739.
  • Miller M. F., Franchi I. A., Sexton A. S., and Pillinger C. T. 1999. High precision delta O-17 isotope measurements of oxygen from silicates and other oxides: Method and applications. Rapid Communications in Mass Spectrometry 13:12111217.
  • Misawa K. 2004. The Yamato 980459 olivine-phyric shergottite consortium. Antarctic Meteorite Research 17:112.
  • Mohapatra R. K., Schwenzer S. P., Herrmann S., Murty S. V. S., Ott U., and Gilmour J. D. 2009. Noble gases and nitrogen in Martian meteorites Dar al Gani 476, Sayh al Uhaymir 005 and Lewis Cliff 88516: EFA and extra neon. Geochimica et Cosmochimica Acta 73:15051522.
  • Monders A. G., Médard E., and Grove T. L. 2007. Phase equilibrium investigations of the Adirondack class basalts from the Gusev plains, Gusev crater, Mars. Meteoritics & Planetary Science 42:131148.
  • Moriguti T. and Nakamura E. 1998. Across-arc variation of Li isotopes in lavas and implications for crust/mantle recycling at subduction zones. Earth and Planetary Science Letters 163:167174.
  • Musselwhite D. S., Dalton H. A., Kiefer W. S., and Treiman A. H. 2006. Experimental petrology of the basaltic shergottite Yamato-980459: Implications for the thermal structure of the Martian mantle. Meteoritics & Planetary Science 41:12711290.
  • Neal C., Ely J., and Jain J. 2001. New platinum-group element (PGE) data for Martian meteorites: The influence of igneous processing. Proceedings, 32nd Lunar and Planetary Science Conference. p. 1682.
  • Nier A. O. 1950. A redetermination of the relative abundances of the isotopes of carbon, nitrogen, oxygen, argon, and potassium. Physical Review C 77:789.
  • Norman M. 1999. The composition and thickness of the crust of Mars estimated from REE and Nd isotopic compositions of Martian meteorites. Meteoritics & Planetary Science 34:439449.
  • Ottolini L., Le Fèvre B., and Vannucci R. 2004. Direct assessment of mantle boron and lithium contents and distribution by SIMS analyses of peridotite minerals. Earth and Planetary Science Letters 228:1936.
  • Papike J. J., ed. 1998. Comparative planetary mineralogy: Chemistry of melt-derived pyroxene, feldspar, and olivine. In Planetary materials. Washington, DC: Mineralogical Society of America. pp. G1G11.
  • Penniston-Dorland S. C., Sorensen S. S., Ash R. D., and Khadke S. V. 2010. Lithium isotopes as a tracer of fluids in a subduction zone mélange: Franciscan Complex, CA. Earth and Planetary Science Letters 292:181190.
  • Penniston-Dorland S. C., Bebout G. E., Pogge von Strandmann P. A. E., Elliott T., and Sorensen S. S. 2012. Lithium and its isotopes as tracers of subduction zone fluids and metasomatic processes: Evidence from the Catalina Schist, California, USA. Geochimica et Cosmochimica Acta 77:530545.
  • Riches A. J. V., Liu Y., Day J. M. D., Puchtel I. S., Rumble D., McSween H. Y., Walker R. J., and Taylor L. A. 2011. Petrology and geochemistry of Yamato 984028: A cumulate lherzolitic shergottite with affinities to Y 000027, Y 000047, and Y 000097. Polar Science 4:497514.
  • Rubin A. E., Warren P. H., Greenwood J. P., Verish R. S., Leshin L. A., Hervig R. L., Clayton R. N., and Mayeda T. K. 2000. Los Angeles: The most differentiated basaltic Martian meteorite. Geology 28:10111014.
  • Rudnick R. L., Tomascak P. B., Njo H. B., and Gardner L. R. 2004. Extreme lithium isotopic fractionation during continental weathering revealed in saprolites from South Carolina. Chemical Geology 212:4557.
  • Rumble D. and Irving A. 2009. Dispersion of oxygen isotopic compositions among 42 Martian meteorites determined by laser fluorination: Evidence for assimilation of (ancient) altered crust (abstract #2293). 40th Lunar and Planetary Science Conference. CD-ROM.
  • Schmidt M. E., and McCoy T. J. 2010. The evolution of a heterogeneous Martian mantle: Clues from K, P, Ti, Cr, and Ni variations in Gusev basalts and shergottite meteorites. Earth and Planetary Science Letters 296:6777.
  • Schwenzer S. P., Schwanethal J., Ott U., Tindle A. G., Anand M., and Kelley S. P. 2011. ALHA77005: Monitor for terrestrial influence on noble gases and analouge for Mars Meteoritics & Planetary Science 46 :A209.
  • Seitz H.-M., Brey G. P., Lahaye Y., Durali S., and Weyer S. 2004. Lithium isotopic signatures of peridotite xenoliths and isotopic fractionation at high temperature between olivine and pyroxenes. Chemical Geology 212:163177.
  • Seitz H.-M., Brey G. P., Weyer S., Durali S., Ott U., Münker C., and Mezger K. 2006. Lithium isotope compositions of Martian and lunar reservoirs. Earth and Planetary Science Letters 245:618.
  • Seitz H.-M., Brey G. P., Zipfel J., Ott U., Weyer S., Durali S., and Weinbruch S. 2007. Lithium isotope composition of ordinary and carbonaceous chondrites, and differentiated planetary bodies: Bulk solar system and solar reservoirs. Earth and Planetary Science Letters 260:582596.
  • Shearer C. K., Burger P. V., Papike J. J., Borg L. E., Irving A. J., and Herd C. D. K. 2008. Petrogenetic linkages among Martian basalts: Implications based on trace element chemistry of olivine. Meteoritics & Planetary Science 43:12411258.
  • Shih C. Y., Nyquist L. E., Bogard D. D., McKay G. A., Wooden J. L., Bansal B. M., and Wiesmann H. 1982. Chronology and petrogenesis of young achondrites, Shergotty, Zagami, and ALHA77005: Late magmatism on a geologically active planet. Geochimica et Cosmochimica Acta 46:23232344.
  • Shirai N. and Ebihara M. 2004. Chemical characteristics of a Martian meteorite, Yamato 980459. Antarctic Meteorite Research 17:5567.
  • Smith J. V. and Hervig R. L. 1979. Shergotty meteorite: Mineralogy, petrography, and minor elements. Meteoritics 14:121142.
  • Smith J. V., Steele I. M., and Leitch C. A. 1983. Mineral chemistry of the shergottites, nakhlites, Chassigny, Brachina, pallasites and urelites. Journal of Geophysical Research 88:B229B236.
  • Stolper E. M. and McSween H. Y. 1979. Petrology and origin of the shergottite meteorites. Geochimica et Cosmochimica Acta 43:14751498.
  • Taylor L. A., Nazarov M. A., Shearer C. K., Jr., Aaaaa H. Y. M., Cahill J., Neal C. R., Ivanova M. A., Barsukova L. D., Lentz R. C., Clayton R. N., and Mayeda T. K. 2002. Martian meteorite Dhofar 019: A new shergottite. Meteoritics & Planetary Science 37:11071128.
  • Teng F.-Z., McDonough W. F., Rudnick R. L., and Walker R. J. 2006. Diffusion-driven extreme lithium isotopic fractionation in country rocks of the Tin Mountain pegmatite. Earth and Planetary Science Letters 243:701710.
  • The Meteoritical Society. 2012. Meteoritical Bulletin Database: Northwest Africa 6234. http://www.lpi.usra.edu/meteor/metbull.php. Last accessed 17 July, 2012.
  • Tomascak P. B., Tera F., Helz R. T., and Walker R. J. 1999. The absence of lithium isotope fractionation during basalt differentiation: New measurements by multicollector sector ICP-MS. Geochimica et Cosmochimica Acta 63:907910.
  • Treiman A. H. 1996. The perils of partition: Difficulties in retrieving magma compositions from chemically equilibrated basaltic meteorites. Geochimica et Cosmochimica Acta 60:147155.
  • Treiman A. H. 2003. Chemical compositions of Martian basalts (shergottites): Some inferences on basalt formation, mantle metasomatism, and differentiation in Mars. Meteoritics & Planetary Science 38:18491864.
  • Treiman A. H. 2005. The nakhlite meteorites: Augite-rich igneous rocks from Mars. Chemie der Erde-Geochemistry 65:203270.
  • Treiman A. H., Lindstrom D. J., and Martinez R. R. 1994. The parent magma of xenoliths in shergottite EETA79001: Bulk and trace element composition inferred from magmatic inclusions. Proceedings, 25th Lunar and Planetary Science Conference. pp. 14171418.
  • Treiman A. H., Gleason J. D., and Bogard D. D. 2000. The SNC meteorites are from Mars. Planetary and Space Science 48:12131230.
  • Tschermak G. 1872. Die Meteofiten von Shergotty und Gopalpur. Sitzungs-Berichte der Mathematish-naturwissenschaftlichen Classe, Akademie der Wissenschaften Wien 65:122146.
  • Tsuno K. and Dasgupta R. 2011. Melting phase relation of nominally anhydrous, carbonated pelitic-eclogite at 2.5–3.0 GPa and deep cycling of sedimentary carbon. Contributions to Mineralogy and Petrology 161:743763.
  • Usui T., Sanborn M., Wadhwa M., and McSween H. Y., Jr. 2010. Petrology and trace element geochemistry of Robert Massif 04261 and 04262 meteorites, the first examples of geochemically enriched lherzolitic shergottites. Geochimica et Cosmochimica Acta 74:72837306.
  • Wänke H. 1981. Constitution of terrestrial planets. Philosophical Transactions of the Royal Society of London Series A—Mathematical Physical and Engineering Sciences 303:287302.
  • Wänke H. and Dreibus G. 1988. Chemical-composition and accretion history of terrestrial planets. Philosophical Transactions of the Royal Society of London Series A—Mathematical Physical and Engineering Sciences 325:545557.
  • Warren P. H. and Kallemeyn G. W. 1997. Yamato-793605, EET 79001, and other presumed Martian meteorites: compositional clues to their origins. Antarctic Meteorite Research 10:6181.
  • Warren P. H., Kallemeyn G. W., and Kyte F. T. 1999. Origin of planetary cores: Evidence from highly siderophile elements in Martian meteorites. Geochimica et Cosmochimica Acta 63:21052122.
  • Warren P. H., Greenwood J. P., Richardson J. W., Rubin A. E., and Verish R. S. 2000. Geochemistry of Los Angeles, a ferroan, La-and Th-rich basalt from Mars (abstract #2001). 31st Lunar and Planetary Science Conference. CD-ROM.
  • Warren P. H., Greenwood J. P., and Rubin A. E. 2004. Los Angeles: A tale of two stones. Meteoritics & Planetary Science 39:137156.
  • Xirouchakis D., Draper D. S., Schwandt C. S., and Lanzirotti A. 2002. Crystallization conditions of Los Angeles, a basaltic Martian meteorite. Geochimica et Cosmochimica Acta 66:18671880.
  • Zipfel J., Scherer P., Spettel B., Dreibus G., and Schultz L. 2000. Petrology and chemistry of the new shergottite Dar al Gani 476. Meteoritics & Planetary Science 35:95106.