Journal
EARTH AND PLANETARY SCIENCE LETTERS
Volume 517, Issue -, Pages 38-49Publisher
ELSEVIER SCIENCE BV
DOI: 10.1016/j.epsl.2019.04.005
Keywords
Hadean; detrital zircon; Jack Hills; scanning ion imaging; unsupported radiogenic lead
Categories
Funding
- Australia Research Council Centre of Excellence for Core to Crust Fluid Systems (CCFS) [1333]
- Knut and Alice Wallenberg Foundation
- Swedish Research Council
- National Natural Science Foundation of China [41672186, 41502178]
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The recent discovery of Pb* (radiogenic lead)-enriched domains (PEDs) in zircon using high-resolution scanning ion imaging, atom probe tomography and transmission electron microscopy indicates that the U-Pb isotopic system in zircon can be affected not only by Pb* loss but also by intra-crystalline Pb* enrichment. However, the formation mechanism of PEDs and the consequences for in-situ U-Pb dating remain elusive. To further understand these issues, scanning ion imaging and U-Pb dating were carried out on 51 Hadean detrital zircon grains from the Jack Hills, Western Australia. Of these, 8 grains were found to contain micrometer-scale PEDs with elevated Pb-207 and Pb-206 in the ion images. Isotope profiles across these PEDs confirm that they represent unsupported Pb* resulting from intra-grain mobilization and local enrichment of Pb* during ancient overprinting events. The PEDs are rare in most grains, with only 1-3 Pb* hotspots present in any similar to 70 mu m x 70 mu m imaged area, and are located either in dark-CL, high-U growth zones, or associated with bright-CL, low-Th recrystallized domains, suggesting that they were likely formed by local-scale processes. The PEDs located in dark-CL, high-U growth zones likely resulted from Pb* trapped in local, interconnected pathways produced by radiation damage during thermal overprinting events. Those associated with bright-CL, low-Th domains are interpreted as Pb* concentrated in nanoscale pores formed during fluid-present recrystallization of non-metamict zircon. Our interpretations therefore imply that intra-crystalline enrichment of Pb* in zircon can occur at various scales and through diverse mechanisms. Age calculations based on the ion images demonstrate that incorporation of PEDs in conventional in-situ SIMS spots produces spuriously old ages that are either reversely discordant or concordant, depending on the time of Pb* mobilization and the analytical precision. The implication is that careful investigation of intra-grain distribution of U-Th-Pb isotopes is required in order to better understand the U-Pb isotopic system and to obtain reliable crystallization ages for ancient zircons affected by complex Pb* mobilization and redistribution. (C) 2019 Elsevier B.V. All rights reserved.
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