Calcium-48 isotopic anomalies in bulk chondrites and achondrites: Evidence for a uniform isotopic reservoir in the inner protoplanetary disk

Thermal ionization mass spectrometry (TIMS) was used to measure the calcium isotopic compositions of carbonaceous, ordinary, enstatite chondrites as well as eucrites and aubrites. We find that after correction for mass-fractionation by internal normalization to a fixed Ca-42/Ca-44 ratio, the Ca-43/Ca-44 and Ca-46/Ca-44 ratios are indistinguishable from terrestrial ratios. In contrast, the Ca-49/Ca-44 ratios show significant departure from the terrestrial composition (from -2 epsilon in eucrites to +4 epsilon in CO and CV chondrites). Isotopic anomalies in epsilon Ca-48 correlate with epsilon Ti-50: epsilon Ca-48 = (1.09 +/- 0.11) x epsilon Ti-50 + (0.03 +/- 0.14). Further work is needed to identify the carrier phase of Ca-48-Ti-50 anomalies but we suggest that it could be perovskite and that the stellar site where these anomalies were created was also responsible for the nucleosynthesis of the bulk of the solar system inventory of these nuclides. The Earth has identical Ca-48 isotopic composition to enstatite chondrites (EH and EL) and aubrites. This adds to a long list of elements that display nucleosynthetic anomalies at a bulk planetary scale but show identical or very similar isotopic compositions between enstatite chondrites, aubrites, and Earth. This suggests that the inner protoplanetary disk was characterized by a uniform isotopic composition (IDUR for Inner Disk Uniform Reservoir), sampled by enstatite chondrites and aubrites, from which the Earth drew most of its constituents. The terrestrial isotopic composition for O-17, (48) ca, Ti-50, Ni-62 and Mo-92 is well reproduced by a mixture of 91% enstatite, 7% ordinary, and 2% carbonaceous chondrites. The Earth was not simply made of enstatite chondrites but it formed from the same original material that was later modified by nebular and disk processes. The Moon-forming impactor probably came from the same region as the other embryos that made the Earth, explaining the strong isotopic similarity between lunar and terrestrial rocks. (C) 2014 Elsevier B.V. All rights reserved.