Isotopic composition of zinc, copper, and iron in lunar samples

We determined by ICP-MS the concentrations and isotopic ratios of Fe, Cu, and Zn in the Ti-rich lunar basalt 74275, in the lunar orange glass 74220, and in up to 10 lunar soils, namely, 14163, 15231, 64501, 66041, 68841, 69941, 70011, 72501, 7508 1, and 76501. Two analyses of zinc in lunar basalt 74275 give delta Zn-66 = 0.17 parts per thousand and 0.75 parts per thousand, values within the range of those measured in terrestrial basalts; copper in lunar basalt 74275 has delta Cu-65 similar to +1.4 parts per thousand, which is isotopically heavier than values observed in terrestrial basalts. In the orange glass, we measured delta Fe-56 = -0.24 parts per thousand, delta Cu-65 = -0.42 parts per thousand, and delta Zn-66 similar to -3.6 parts per thousand. These values of delta are more negative than those obtained for 74275 and for typical lunar basalts, but for Cu, comparable to those observed in terrestrial sulfides and meteorites. In lunar soils we found 0.11 parts per thousand <= delta Fe-56 <= 0.51 parts per thousand 2.6 parts per thousand <= delta Cu-65 <= 4.5 parts per thousand, and 2.2 parts per thousand <= delta Zn-66 <= 6.4 parts per thousand. Insofar as we can generalize from a small sample set, S, Fe, Cu, Zn, and Cd show similar trends in isotopic fractionation on the Moon. Lunar basalts have nearly terrestrial isotopic ratios. Relative to the lunar basalt 74275, the pyroclastic glass 74220 is enriched in the lighter isotopes of Fe, Cu, and Zn, and the soils are enriched in the heavier isotopes of Fe, Cu, and Zn. The patterns in the basalts are likely inherited from the source material; the light-isotope enrichments seen in the orange glass originated during lava fountaining or, less probably, during partial condensation of vapor; and the heavy-isotope enrichments in the lunar soils were likely created by a combination of processes that included micrometeorite vaporization and sputtering. In the orange glass, the light-isotope enrichments (relative to lunar basalts) of Zn are larger than those of Cu. If these enrichments reflect accurately the isotopic composition of the gas, they suggest that Cu is more volatile than Zn in the liquid from which the gas derived. A simple model built on the known flux of micrometeorites to the lunar surface and a published estimate that micrometeorites generate 10 times their own mass of vapor, predicts heavy-isotope enrichments comparable to those observed in soils but only if the regolith gardening rate is set at about one twentieth of the generally accepted value of 1 cm/My. This discrepancy may reflect the difference in the time constants for micrometeorite milling and decimeter-scale gardening, or the importance of sputtering. (c) 2006 Published by Elsevier Inc.