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Published October 2015 | public
Journal Article

In situ SIMS oxygen isotope analyses: Evidence for the formation of aluminum-rich chondrules from ordinary chondrites

Abstract

Aluminum-rich chondrules (ARCs), which share mineralogic and chemical properties with both Ca, Al-rich inclusions (CAIs) and ferromagnesian chondrules, play an important role in revealing their temporal and petrogenetic relationships. In this work, seven ARCs were found in three ordinary chondrites GRV 022410 (H4), GRV 052722 (H3.7) and Julesburg (L3.6). They contain bulk Al_2O_3 ∼ 17%–33% and exhibit igneous textures composed of olivine, high- and low-Ca pyroxene, plagioclase, spinel and glass. In situ SIMS analyses show that ARCs have oxygen isotopic compositions (δ^(18)O=−6.1‰–7.1‰; δ^(17)O= −4.5‰–5.1‰) close to ferromagnesian chondrules but far more depleted in ^(16)O than CAIs (δ^(18)O=−40‰; δ^(17)O=−40‰). Most ARCs plot close to the terrestrial mass fractionation (TF) line, and a few between the TF and carbonaceous chondrite anhydrous mixing (CCAM) lines. Plagioclase, nepheline and glass suffered O-isotopic exchanges during the metamorphism processes in the parent body. Spinel, olivine and pyroxene represent the primary O-isotopic compositions of ARCs, and define a fitted line with a slope of ∼ 0.7±0.1. Compared with the results of previous studies, shallower slope as well as more depleted ^(16)O compositions further demonstrates that ARCs in ordinary chondrites are not a simple mixing product of ferromagnesian chondrules and CAIs. Instead, they probably experienced higher-degree oxygen isotope exchange with a ^(16)O-poor nebular gas reservoir during multiple melting episodes.

Additional Information

© 2015 Springer. Received October 25, 2014; accepted March 18, 2015; published online May 29, 2015. SPECIAL TOPIC: Microbeam Analytical Techniques and Their Applications to Earth Science. The authors thank the Polar Research Institute of China for providing Antarctic meteorites. This work was supported by the Natural Science Foundation of Jiangsu Province (Grant No. BK20131040), the National Natural Science Foundation of China (Grants Nos. 41403056, 41173076, 41273079, 41003026), and the Minor Planet Foundation of China.

Additional details

Created:
August 22, 2023
Modified:
October 25, 2023