Abstract
We present new mass independent and mass dependent Cr isotope compositions for meteorites measured by double spike thermal ionisation mass spectrometry. Small differences in both mass independent 53Cr and 54Cr relative to the Bulk Silicate Earth are reported and are very similar to previously published values. Carbonaceous chondrites are characterised by an excess in 54Cr compared to ordinary and enstatite chondrites which make mass independent Cr isotopes a useful tool for distinguishing between meteoritic groups. Mass dependent stable Cr isotope compositions for the same samples are also reported. Carbonaceous and ordinary chondrites are identical within uncertainty with average δ53Cr values of −0.118±0.040‰ and −0.143±0.074‰ respectively. The heaviest isotope compositions are recorded by an enstatite chondrite and a CO carbonaceous chondrite, both of which have relatively reduced chemical compositions implying some stable Cr isotope fractionation related to redox processes in the circumstellar disk. The average δ53Cr values for chondrites are within error of the estimate for the Bulk Silicate Earth (BSE) also determined by double spiking. The lack of isotopic difference between chondritic material and the BSE provides evidence that Cr isotopes were not fractionated during core formation on Earth. A series of high-pressure experiments was also carried out to investigate stable Cr isotope fractionation between metal and silicate and no demonstrable fractionation was observed, consistent with our meteorites data. Mass dependent Cr isotope data for achondrites suggest that Cr isotopes are fractionated during magmatic differentiation and therefore further work is required to constrain the Cr isotopic compositions of the mantles of Vesta and Mars.
Highlights
Variations in chemical composition in the Solar System reflect early nebular processes as well as planetary accretion and differentiation
Radiogenic ε53Cr values for meteorites analysed in this study range from 0.14 to 1.03 and nucleosynthetic ε54Cr values between −0.71 and 1.45
Carbonaceous chondrites show excess 54Cr compared to ordinary chondrites (Fig. 2)
Summary
Variations in chemical composition in the Solar System reflect early nebular processes as well as planetary accretion and differentiation. Metal–silicate differentiation (or core formation) is a dramatic process that transforms the budgets of slightlyto strongly-siderophile elements in the residual bulk silicate Earth (BSE). A new tool to assess the removal of elements into the core is to utilise the fractionation of stable isotopes between metal and silicate, which provide insights into the reactions occurring during core formation and constraints on key physical parameters such as temperature, pressure and oxygen fugacity Such mass dependent isotopic variations have already been utilised in this way for Si (Georg et al, 2007; Armytage et al, 2011; Zambardi et al, 2013), Fe (Williams et al, 2012) and Cr (Moynier et al, 2011)
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.