Recent aqueous environments in Martian impact craters: an astrobiological perspective
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[1] R. Mcqueen,et al. Compression of Solids by Strong Shock Waves , 1958 .
[2] G. R. Fowles. Shock Wave Compression of Hardened and Annealed 2024 Aluminum , 1961 .
[3] T. Ahrens,et al. Shock compression of a recrystallized anorthositic rock from Apollo 15 , 1973 .
[4] T. Ahrens,et al. Equations of state and impact-induced shock-wave attenuation on the moon , 1976 .
[5] G. Neukum,et al. Mars: a standard crater curve and possible new time scale. , 1976, Science.
[6] G. E. Duvall,et al. Phase transitions under shock-wave loading , 1977 .
[7] P. Mouginis-Mark. Martian fluidized crater morphology: Variations with crater size, latitude, altitude, and target material , 1979 .
[8] Dennis E. Grady,et al. Shock deformation of brittle solids , 1980 .
[9] W. Hartmann. Does crater “saturation equilibrium” occur in the solar system? , 1984 .
[10] H. Melosh. Impact ejection, spallation, and the origin of meteorites , 1984 .
[11] H. Melosh. Ejection of rock fragments from planetary bodies , 1985 .
[12] Michael H. Carr,et al. Water on Mars , 1987, Nature.
[13] Warwick F. Vincent,et al. Microbial ecosystems of Antarctica , 1988 .
[14] F. Costard. Thickness of Sedimentary Deposits at the Mouth of Outflow Channels , 1988 .
[15] V. P. Shashkina,et al. Inhomogeneities in the Upper Levels of the Martian Cryolithosphere , 1988 .
[16] N. Barlow. Crater size-frequency distributions and a revised Martian relative chronology , 1988 .
[17] L. Rothschild,et al. Earth analogs for Martian life. Microbes in evaporites, a new model system for life on Mars. , 1990, Icarus.
[18] V. Gulick,et al. Origin and evolution of valleys on Martian volcanoes , 1990 .
[19] J. M. McGlaun,et al. CTH: A three-dimensional shock wave physics code , 1990 .
[20] M. Carr. D/H on Mars - Effects of floods, volcanism, impacts, and polar processes , 1990 .
[21] T. Gold,et al. The deep, hot biosphere. , 1998, Proceedings of the National Academy of Sciences of the United States of America.
[22] D. Gilichinsky,et al. Long-term preservation of microbial ecosystems in permafrost. , 1992, Advances in space research : the official journal of the Committee on Space Research.
[23] J. Crowe,et al. Anhydrobiosis: a strategy for survival. , 1992, Advances in space research : the official journal of the Committee on Space Research.
[24] David A. Paige,et al. The thermal stability of near-surface ground ice on Mars , 1992, Nature.
[25] N. Barlow,et al. The Martian impact cratering record. , 1992 .
[26] Stephen M. Clifford,et al. A model for the hydrologic and climatic behavior of water on Mars , 1993 .
[27] R. Wharton. Stromatolitic Mats in Antarctic Lakes , 1994 .
[28] Todd O. Stevens,et al. Lithoautotrophic Microbial Ecosystems in Deep Basalt Aquifers , 1995, Science.
[29] C. McKay,et al. Paleolakes on Mars , 1995, Journal of paleolimnology.
[30] T. McMeekin,et al. Ecology and physiology of psychrophilic bacteria from Antarctic saline lakes and sea ice , 1995 .
[31] N. Cabrol,et al. A morphological view on potential niches for exobiology on Mars. , 1995, Planetary and space science.
[32] D. Gilichinsky,et al. Preservation of cell structures in permafrost: a model for exobiology. , 1995, Advances in space research : the official journal of the Committee on Space Research.
[33] R. Forsythe,et al. A case for ancient evaporite basins on Mars , 1995 .
[34] M. Potts. The anhydrobiotic cyanobacterial cell , 1996 .
[35] R. Ocampo,et al. Porphyrins in Upper Jurassic source rocks and correlations with other source rock descriptors , 1996 .
[36] C. Hibbitts,et al. Impact crater lakes on Mars , 1996 .
[37] V. Soina,et al. Microorganisms and enzyme activity in permafrost after removal of long-term cold stress , 1996 .
[38] D. Schindler,et al. Past ultraviolet radiation environments in lakes derived from fossil pigments , 1997, Nature.
[39] Nathalie A. Cabrol,et al. Limnologic Analysis of Gusev Crater Paleolake, Mars , 1997 .
[40] D. Hafenbradl,et al. Pyrolobus fumarii, gen. and sp. nov., represents a novel group of archaea, extending the upper temperature limit for life to 113°C , 1997, Extremophiles.
[41] D. Kring. Air blast produced by the Meteor Crater impact event and a reconstruction of the affected environment , 1997 .
[42] Nathalie A. Cabrol,et al. Ma'adim Vallis Evolution: Geometry and Models of Discharge Rate , 1998 .
[43] Nathalie A. Cabrol,et al. Duration of the Ma'adim Vallis/Gusev Crater Hydrogeologic System, Mars , 1998 .
[44] B. Clark. Surviving the limits to life at the surface of Mars , 1998 .
[45] Philip E. Long,et al. Observations Pertaining to the Origin and Ecology of Microorganisms Recovered from the Deep Subsurface of Taylorsville Basin, Virginia , 1998 .
[46] C. McKay,et al. Antarctic paleolake sediments and the search for extinct life on Mars , 1998 .
[47] L. Rothschild,et al. Biopan-survival I: exposure of the osmophiles synechococcus sp. (Nageli) and haloarcula sp. to the space environment , 1998 .
[48] J. Farmer. Thermophiles, early biosphere evolution, and the origin of life on Earth: Implications for the exobiological exploration of Mars , 1998 .
[49] David D. Wynn-Williams,et al. FT-Raman spectroscopic analysis of endolithic microbial communities from Beacon sandstone in Victoria Land, Antarctica , 1998, Antarctic Science.
[50] N. Cabrol,et al. Candidate-Landing Sites and Backups for the Mars Surveyor Program in the Schiaparelli. Crater Region , 1999 .
[51] D J Des Marais,et al. Exploring for a record of ancient Martian life. , 1999, Journal of geophysical research.
[52] S. Golubić,et al. Early cyanobacterial fossil record: preservation, palaeoenvironments and identification , 1999 .
[53] V. Gulick. Candidate Mars Surveyor Landing Sites Near Apollinaris Patera , 1999 .
[54] J W Head,et al. Possible ancient oceans on Mars: evidence from Mars Orbiter Laser Altimeter data. , 1999, Science.
[55] M. L. Wade,et al. A Mossbauer investigation of iron-rich terrestrial hydrothermal vent systems: lessons for Mars exploration. , 1999, Journal of geophysical research.
[56] N. Cabrol,et al. Distribution, Classification, and Ages of Martian Impact Crater Lakes , 1999 .
[57] David D. Wynn-Williams,et al. Functional biomolecules of Antarctic stromatolitic and endolithic cyanobacterial communities , 1999 .
[58] Roger E. Summons,et al. 2-Methylhopanoids as biomarkers for cyanobacterial oxygenic photosynthesis , 1999, Nature.
[59] N. Hoffman. White Mars: A New Model for Mars' Surface and Atmosphere Based on CO2 , 2000 .
[60] H. Edwards,et al. Proximal Analysis of Regolith Habitats and Protective Biomolecules in Situ by Laser Raman Spectroscopy: Overview of Terrestrial Antarctic Habitats and Mars Analogs , 2000 .
[61] M. Malin,et al. Evidence for recent groundwater seepage and surface runoff on Mars. , 2000, Science.
[62] C. McKay,et al. Metabolic Activity of Permafrost Bacteria below the Freezing Point , 2000, Applied and Environmental Microbiology.
[63] N. Shrine,et al. Exobiology: Laboratory tests of the impact related aspects of Panspermia , 2000 .
[64] J. William Schopf,et al. The Fossil Record: Tracing the Roots of the Cyanobacterial Lineage , 2000 .
[65] J. M. Moldowan,et al. Chemical Signals for Early Evolution of Major Taxa: Biosignatures and Taxon-Specific Biomarkers , 2000 .
[66] F. Westall,et al. Microfossils and Paleoenvironments in Deep Subsurface Basalt Samples , 2000 .
[67] Daniela Billi,et al. Ionizing-Radiation Resistance in the Desiccation-Tolerant CyanobacteriumChroococcidiopsis , 2000, Applied and Environmental Microbiology.
[68] Barbara A. Cohen,et al. Noble gases in iddingsite from the Lafayette meteorite: Evidence for liquid water on Mars in the last few hundred million years , 2000 .
[69] D. Dickensheets,et al. Tools for Robotic In Situ Optical Microscopy and Raman Spectroscopy on Mars , 2000 .
[70] N. Cabrol,et al. The Evolution of Lacustrine Environments on Mars: Is Mars Only Hydrologically Dormant? , 2001 .
[71] C. McKay,et al. The Search for Life on Mars , 2010 .