The effect of ionizing radiation on the preservation of amino acids on Mars
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[1] Ness,et al. Magnetic Field and Plasma Observations at Mars: Initial Results of the Mars Global Surveyor Mission , 1998, Science.
[2] S. Pizzarello,et al. Amino acids in meteorites. , 1983, Advances in space research : the official journal of the Committee on Space Research.
[3] G. Kepner,et al. Membrane enzyme systems. Molecular size determinations by radiation inactivation. , 1968, Biochimica et biophysica acta.
[4] R. E. Lapp,et al. Nuclear Radiation Physics. , 1949 .
[5] B. Jakosky,et al. Martian neutron leakage spectra , 1988 .
[6] H. Leffmann. Data of geochemistry: United States Geological Survey, Bulletin 695. By Frank Wigglesworth Clarke. 4th edition. 773 pages and index, 8vo. Washington, Government Printing Office, 1920 , 1920 .
[7] E. Kempner,et al. Molecular weight determinations from radiation inactivation. , 1985, Methods in enzymology.
[8] R L Mancinelli,et al. Could organic matter have been preserved on Mars for 3.5 billion years? , 1990, Icarus.
[9] F A Cucinotta,et al. Natural transfer of viable microbes in space. , 2000, Icarus.
[10] B. Mason. Cosmochemistry; Part 1, Meteorites , 1979 .
[11] A. V. Blinov,et al. Sterilization of Martian surface by cosmic radiation , 2002 .
[12] E. Friedmann,et al. Endolithic Microorganisms in the Antarctic Cold Desert , 1982, Science.
[13] J L Bada,et al. Amino acid racemization on Mars: implications for the preservation of biomolecules from an extinct martian biota. , 1995, Icarus.
[14] H. Urey. THE COSMIC ABUNDANCES OF POTASSIUM, URANIUM, AND THORIUM AND THE HEAT BALANCES OF THE EARTH, THE MOON, AND MARS. , 1955, Proceedings of the National Academy of Sciences of the United States of America.
[15] Sherwood Chang,et al. Organic matter in meteorites: molecular and isotopic analyses of the Murchison meteorite. , 1993 .
[16] Philip A. Bland,et al. Meteorite Accumulations on Mars , 1999 .
[17] J. Kasting,et al. The case for a wet, warm climate on early Mars. , 1987, Icarus.
[18] N. Bridges,et al. Erosion rates on Mars and implications for climate change: Constraints from the Pathfinder landing site , 2000 .
[19] G. Horneck,et al. Natural Transfer of Viable Microbes in Space: 1. From Mars to Earth and Earth to Mars , 2000 .
[20] H. J. Moore,et al. Viking landing sites, remote-sensing observations, and physical properties of Martian surface materials , 1989 .
[21] F. Neidhardt,et al. Physiology of the bacterial cell : a molecular approach , 1990 .
[22] J. Greenberg,et al. The chemistry of life's origins , 1993 .
[23] William H. Grover,et al. Development and evaluation of a microdevice for amino acid biomarker detection and analysis on Mars. , 2005, Proceedings of the National Academy of Sciences of the United States of America.
[24] J. Bada. How life began on Earth: a status report , 2004 .
[25] N. Panagakos,et al. Viking landing sites , 1973 .
[26] J. Bada,et al. Determination of alpha-dialkylamino acids and their enantiomers in geological samples by high-performance liquid chromatography after derivatization with a chiral adduct of o-phthaldialdehyde. , 1995, Journal of chromatography. A.
[27] C. Stoker,et al. Organic degradation under simulated Martian conditions. , 1997, Journal of geophysical research.
[28] J. Ferris. The chemistry of life's origin. , 1984, Chemical and engineering news : "news edition" of the American Chemical Society.
[29] J. Bada. Amino Acid Cosmogeochemistry , 1991 .
[30] S. Squyres,et al. Early Mars: How Warm and How Wet? , 1994, Science.
[31] G. Flynn,et al. An assessment of the meteoritic contribution to the Martian soil , 1990 .
[32] E. Kempner,et al. [6] Molecular weight determinations from radiation inactivation , 1985 .