Petrologic evidence for low-temperature, possibly flood evaporitic origin of carbonates in the ALH84001 meteorite.
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[1] Y. Miura,et al. Orthopyroxenite ALH84001 and shergottite ALH77005: Additional evidence for a martian origin from noble gases , 1995 .
[2] Harry Y. McSween,et al. An Evaporation Model for Formation of Carbonates in the ALH84001 Martian Meteorite , 1998 .
[3] S. Brantley,et al. Chapter 4. CHEMICAL WEATHERING RATES OF PYROXENES AND AMPHIBOLES , 1995 .
[4] S. Brantley,et al. Chemical weathering rates of pyroxenes and amphiboles , 1995 .
[5] D. Norton,et al. Transport phenomena in hydrothermal systems; cooling plutons , 1977 .
[6] L. Leshin,et al. Oxygen Isotopic Constraints on the Genesis of Carbonates from Martian Meteorite ALH84001 , 1998 .
[7] R. Haberle,et al. The seasonal behavior of water on Mars , 1992 .
[8] Robert G. Bryant,et al. The Chemical Evolution of the Brines of Chott EL Djerid, Southern Tunisia, After an Exceptional Rainfall Event in January 1990 , 1994 .
[9] Mark S. Ghiorso,et al. 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 , 1995 .
[10] H. Eugster,et al. Behavior of major solutes during closed-basin brine evolution , 1979 .
[11] V. R. Baker,et al. Ancient oceans, ice sheets and the hydrological cycle on Mars , 1991, Nature.
[12] A. J. T. Jull,et al. Isotopic composition of carbonates in the SNC meteorites, Allan Hills 84001 and Zagami , 1997 .
[13] J. Beck,et al. Isotopic evidence for a terrestrial source of organic compounds found in martian meteorites Allan Hills 84001 and Elephant Moraine 79001. , 1998, Science.
[14] P. Warren. Lunar and Martian Meteorite Delivery Services , 1994 .
[15] E. Scott,et al. Carbonates in fractures of Martian meteorite Allan Hills 84001: Petrologic evidence for impact origin , 1998, Meteoritics & planetary science.
[16] C. Lécuyer,et al. Formation of carbonates in the Tatahouine meteorite. , 1998, Science.
[17] R. Forsythe,et al. A case for ancient evaporite basins on Mars , 1995 .
[18] H. Newsom. Hydrothermal alteration of impact melt sheets with implications for Mars , 1980 .
[19] R. Zare,et al. Search for Past Life on Mars: Possible Relic Biogenic Activity in Martian Meteorite ALH84001 , 1996, Science.
[20] H. McSween,et al. Magnetite whiskers and platelets in the ALH84001 Martian meteorite: evidence of vapor phase growth. , 1996, Geochimica et cosmochimica acta.
[21] Mark S. Ghiorso,et al. Chemical mass transfer in magmatic processes , 1987 .
[22] I. P. Wright,et al. Record of fluidrock interactions on Mars from the meteorite ALH84001 , 1994, Nature.
[23] J. Gat,et al. The isotope composition of evaporating brines: Effect of the isotopic activity ratio in saline solutions , 1975 .
[24] H. Melosh. Impact Cratering: A Geologic Process , 1986 .
[25] R. Ash,et al. A 4-Gyr shock age for a martian meteorite and implications for the cratering history of Mars , 1996, Nature.
[26] Massimo Menenti,et al. Physical aspects and determination of evaporation in deserts applying remote sensing techniques , 1984 .
[27] John H. Jones,et al. The history of Martian volatiles , 1997 .
[28] P. Wyllie,et al. Liquid Immiscibility in the Join NaAlSi3O8−CaCO3 to 2.5 GPa and the Origin of Calciocarbonatite Magmas , 1996 .
[29] U. Schärer,et al. A SEM-ATEM and stable isotope study of carbonates from the Haughton impact crater, Canada , 1994 .
[30] H Y McSween,et al. The chemical composition of Martian soil and rocks returned by the mobile alpha proton X-ray spectrometer: preliminary results from the X-ray mode. , 1997, Science.
[31] R. Berner,et al. X-ray photoelectron studies of the mechanism of iron silicate dissolution during weathering , 1983 .
[32] J. Goswami,et al. Nuclear tracks and light noble gases in Allan Hills 84001: Preatmospheric size, fall characteristics, cosmic‐ray exposure duration and formation age , 1997 .
[33] R. M. Lloyd. Oxygen isotope enrichment of sea water by evaporation , 1966 .
[34] D P Glavin,et al. A search for endogenous amino acids in martian meteorite ALH84001. , 1998, Science.
[35] E. Scott,et al. Petrological evidence for shock melting of carbonates in the martian meteorite ALH84001 , 1997, Nature.
[36] P. Wyllie. Origin of Carbonatites: Evidence from Phase Equilibrium Studies , 1989 .
[37] Thomas J. Ahrens,et al. Shock compression of feldspars , 1969 .
[38] Harry Y. McSween,et al. A possible high-temperature origin for the carbonates in the martian meteorite ALH84001 , 1996, Nature.
[39] R. M. Henry,et al. The seasonal variation of atmospheric pressure on Mars as affected by the south polar cap , 1979 .
[40] Virginia C. Gulick,et al. Channels and valley networks. , 1992 .
[41] H. Füchtbauer. Sediments and sedimentary rocks , 1974 .
[42] M. Mellon,et al. Geographic variations in the thermal and diffusive stability of ground ice on Mars , 1993 .
[43] A. Treiman. A petrographic history of martian meteorite ALH84001: Two shocks and an ancient age , 1995 .
[44] D. Mittlefehldt,et al. ALH84001, a cumulate orthopyroxenite member of the martian meteorite clan , 1994 .
[45] J. Mcgee,et al. Thermal and mechanical history of granulated norite and pyroxene anorthosite clasts in breccia 73255 , 1979 .
[46] Michael H. Carr. Water on early Mars. , 1996, Ciba Foundation symposium.
[47] W. Boynton,et al. Petrography and bulk chemistry of Martian orthopyroxenite ALH84001: implications for the origin of secondary carbonates. , 1997, Geochimica et Cosmochimica Acta.
[48] G. Kallemeyn,et al. Siderophile trace elements in ALH84001, other SNC meteorites and eucrites: Evidence of heterogeneity, possibly time-linked, in the mantle of Mars , 1996 .
[49] M. Burkland,et al. Noble gases in orthopyroxenite ALH84001: A different kind of martian meteorite with an atmospheric signature , 1995 .
[50] M. Reheis. Gypsic soils on the Kane alluvial fans, Big Horn County, Wyoming , 1987 .
[51] D. Hillel,et al. A SIMULATION STUDY OF THE DRYING‐FRONT PHENOMENON , 1974 .
[52] A. Goresy,et al. Efremovka E49: A compact type-A CAI containing a partially molten spinel-melilite-diopside xenolith , 1994 .
[53] N. Boynton,et al. Minor/major element variation within and among diogenite and howardite orthopyroxenite groups , 1992 .
[54] E. Gibson,et al. Low-Temperature Carbonate Concretions in the Martian Meteorite ALH84001: Evidence from Stable Isotopes and Mineralogy , 1997, Science.
[55] Joseph L. Kirschvink,et al. Paleomagnetic Evidence of a Low-Temperature Origin of Carbonate in the Martian Meteorite ALH84001 , 1997, Science.