High precision iron isotope measurements of meteoritic material by cold plasma ICP-MS
暂无分享,去创建一个
[1] A. Anbar,et al. Nonbiological fractionation of Fe isotopes: evidence of an equilibrium isotope effect , 2003 .
[2] Henry J Sun,et al. Isotopic fractionation between Fe(III) and Fe(II) in aqueous solutions , 2002 .
[3] A. Anbar,et al. Iron isotopes in hot springs along the Juan de Fuca Ridge , 2001 .
[4] S. S. Russell,et al. High Precision Iron Isotope Compositions in Components From the Allende CV3 Meteorite by MC-ICP-MS , 2001 .
[5] M. Zolensky,et al. A terrestrial origin for sulfate veins in CI1 chondrites , 2001 .
[6] J. Luck,et al. Cu and Zn isotopic variations in carbonaceous chondrites and iron meteorites. J.M. , 2001 .
[7] E. Hauri,et al. Iron Isotope Measurements of Meteorites , 2001 .
[8] G. Rossman,et al. Theoretical estimates of equilibrium Fe-isotope fractionations from vibrational spectroscopy , 2001 .
[9] R. K. O’nions,et al. Isotopic homogeneity of iron in the early solar nebula , 2001, Nature.
[10] S. Tanner,et al. Matrix-induced isotopic mass fractionation in the ICP-MS , 2001 .
[11] R. Carlson,et al. Extending the 107Pd-107Ag chronometer to low Pd/Ag meteorites with multicollector plasma-ionization mass spectrometry , 2001 .
[12] R. Pesch,et al. MC-ICPMS -- High Resolution Isotope Ratio Measurements of Fe and Ca , 2001 .
[13] E. Hauri,et al. Precise Iron Isotope Measurements Using Cold Plasma ICP-MS , 2001 .
[14] A. Anbar,et al. Precise determination of mass-dependent variations in the isotopic composition of molybdenum using MC-ICPMS. , 2001, Analytical chemistry.
[15] T. Stephan,et al. The Chemical Heterogeneity of CI Chondrites , 2001 .
[16] C. Alexander,et al. Iron isotopes in chondrules: Implications for the role of evaporation during chondrule formation , 2001 .
[17] R. Ash,et al. The formation of chondrules at high gas pressures in the solar nebula. , 2000, Science.
[18] M. Bourot‐Denise,et al. The lack of potassium‐isotopic fractionation in Bishunpur chondrules , 2000 .
[19] Francis Albarède,et al. High-precision analysis of Pb isotope ratios by multi-collector ICP-MS , 2000 .
[20] J. Bridges,et al. The iodine‐xenon system in clasts and chondrules from ordinary chondrites: Implications for early solar system chronology , 2000 .
[21] A. Anbar,et al. Nonbiological fractionation of iron isotopes. , 2000, Science.
[22] Reynolds,et al. Secular variation of iron isotopes in north atlantic deep water , 2000, Science.
[23] B. Beard,et al. Correction of instrumentally produced mass fractionation during isotopic analysis of fe by thermal ionization mass spectrometry , 1999 .
[24] Bazylinski,et al. Oxygen and iron isotope studies of magnetite produced by magnetotactic bacteria , 1999, Science.
[25] K. Nealson,et al. Iron isotope biosignatures. , 1999, Science.
[26] B. Beard,et al. High precision iron isotope measurements of terrestrial and lunar materials , 1999 .
[27] Francis Albarède,et al. Precise analysis of copper and zinc isotopic compositions by plasma-source mass spectrometry , 1999 .
[28] T. Swindle. Implications of iodine‐xenon studies for the timing and location of secondary alteration , 1998 .
[29] J. Bridges,et al. Elemental redistribution in Tieschitz and the origin of white matrix , 1998 .
[30] R. Carlson,et al. Magnesium Isotopic Fractionation in Tieschitz Chondrules , 1998 .
[31] V. Polyakov. Equilibrium fractionation of the iron isotopes: Estimation from Mössbauer spectroscopy data , 1997 .
[32] J. M. Rhodes. Geochemical stratigraphy of lava flows sampled by the Hawaii Scientific Drilling Project , 1996 .
[33] E. Jagoutz,et al. Sm-Nd System in Single Chondrules from Tieschitz (H3) , 1996 .
[34] A. Bischoff,et al. Carbonates in CI chondrites: clues to parent body evolution. , 1996, Geochimica et cosmochimica acta.
[35] R. Clayton,et al. Oxygen isotopes in separated components of CI and CM meteorites , 1994 .
[36] D. Garrison,et al. Iodine-xenon, chemical, and petrographie studies of Semarkona chondrules: Evidence for the timing of aqueous alteration , 1991 .
[37] G. J. Taylor,et al. Iodine-xenon studies of petrographically and chemically characterized Chainpur chondrules , 1991 .
[38] C. Hohenberg,et al. Tieschitz Chondrules: I-Xe Systematics , 1991 .
[39] J. Voelkening,et al. Iron isotope anomalies , 1989 .
[40] A. Rubin,et al. Ordinary chondrites: Bulk compositions, classification, lithophile-element fractionations and composition-petrographic type relationships , 1989 .
[41] R. Houk,et al. Alleviation of overlap interferences for determination of potassium isotope ratios by inductively coupled plasma mass spectrometry , 1988 .
[42] F. Strelow,et al. THE INFLUENCE OF CROSSLINKAGE ON THE DISTRIBUTION COEFFICIENTS AND ANION EXCHANGE BEHAVIOUR OF SOME ELEMENTS IN HYDROCHLORIC ACID , 1985 .
[43] F. Strelow. Improved separation of iron from copper and other elements by anion-exchange chromatography on a 4% cross-linked resin with high concentrations of hydrochloric acid. , 1980, Talanta.
[44] T. Tombrello,et al. Ca isotope fractionation on the Earth and other solar system materials , 1978 .
[45] P. R. Bevington,et al. Data Reduction and Error Analysis for the Physical Sciences , 1969 .
[46] J. Bigeleisen. Chemistry of Isotopes , 1963, Science.
[47] Akbar Montaser,et al. Inductively coupled plasma mass spectrometry , 1998 .
[48] S. Tanner,et al. Plasma source mass spectrometry : new developments and applications , 1997 .
[49] A. Boss. A concise guide to chondrule formation models. , 1996 .
[50] S. Tanner. Characterization of ionization and matrix suppression in inductively coupled ‘cold’ plasma mass spectrometry , 1995 .
[51] A. J. Walder,et al. Isotope ratio measurement of lead, neodymium and neodymium–samarium mixtures, Hafnium and Hafnium–Lutetium mixtures with a double focusing multiple collector inductively coupled plasma mass spectrometer , 1993 .
[52] Lunar,et al. Chondrules and their origins , 1983 .
[53] G. J. Taylor,et al. Cosmic setting for chondrule formation , 1983 .
[54] E. Anders,et al. Meteorites and the Early Solar System , 1971 .