Sm-Nd systematics of chondrites
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Amelin, Yuri
Rotenberg, E
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Elsevier
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We have studied the147Sm-143Nd and146Sm-142Nd isotopic systems in phosphate fractions and chondrules from six ordinary chondrites and one carbonaceous chondrite, previously dated with Pb-Pb method.147Sm/144Nd ratios vary between 0.182 and 0.191 in phosphates, and between 0.179 and 0.243 in chondrules. The147Sm-143Nd isochron regression through all 34 phosphate and chondrule analyses yields a date of 4588±100 Ma and is in good agreement with more precise Pb-Pb dates of the same chondrites. The initial143Nd/144Nd is 0.50665±0.00014. The same analyses define a146Sm-142Nd isochron with a slope corresponding to146Sm/144Sm=0.0075±0.0027. Initial142Nd/144Nd=1.14160±0.00011 corresponds to ε142Nd=-2.62±0.93. Compilation of the published chondritic whole rock Sm-Nd analyses yields the median147Sm/144Nd=0.1964+0.0003/-0.0007, which is our preferred Chondritic Uniform Reservoir (CHUR) value. Using this value and its error limits, we find the present-day CHUR143Nd/144Nd=0.512637+0.000009/-0.000021 from the chondritic Sm-Nd isochron that includes all available data for whole rocks, chondrules and phosphates. This value is identical within error with the currently accepted number. An estimate of the bulk earth147Sm/144Nd=0.1941±0.0059 is obtained from intercept of chondritic146Sm-142Nd isochron with the terrestrial value of142Nd/144Nd. This estimate is independent of measured Sm/Nd ratios in chondrites. The same approach was applied to published146Sm-142Nd internal isochrons for differentiated meteorites and yielded similar, although less precise, values. Our data are completely consistent with the currently accepted CHUR parameters and substantiate their use as terrestrial reference values.
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Earth and Planetary Science Letters
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2037-12-31
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