Dating kimberlite emplacement with zircon and perovskite ( U ‐ T h)/ H e geochronology

Kimberlites provide rich information about the composition and evolution of cratonic lithosphere. Accurate geochronology of these eruptions is key for discerning spatiotemporal trends in lithospheric evolution, but kimberlites can sometimes be difficult to date with available methods. We explored wh...

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Published in:Geochemistry, geophysics, geosystems : G3 geophysics, geosystems : G3, 2016-11, Vol.17 (11), p.4517-4533
Main Authors: Stanley, Jessica R., Flowers, Rebecca M.
Format: Article
Language:English
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Summary:Kimberlites provide rich information about the composition and evolution of cratonic lithosphere. Accurate geochronology of these eruptions is key for discerning spatiotemporal trends in lithospheric evolution, but kimberlites can sometimes be difficult to date with available methods. We explored whether (U‐Th)/He dating of zircon and perovskite can serve as reliable techniques for determining kimberlite emplacement ages. We obtained zircon and/or perovskite (U‐Th)/He (ZHe, PHe) dates from 16 southern African kimberlites. Most samples with abundant zircon yielded reproducible ZHe dates (≤15% dispersion) that are in good agreement with published eruption ages. The majority of dated zircons were xenocrystic. Zircons with reproducible dates were fully reset during eruption or resided at temperatures above the ZHe closure temperature prior to entrainment in the kimberlite magma. Not dating hazy and radiation damaged grains can help avoid anomalous results for more shallowly sourced zircons that underwent incomplete damage annealing and/or partial He loss during the eruptive process. All seven kimberlites dated with PHe yielded reproducible (≤15% dispersion) and reasonable results. We conducted two preliminary perovskite 4 He diffusion experiments, which suggest a PHe closure temperature of >300°C. Perovskite in kimberlites is unlikely to be xenocrystic and its relatively high temperature sensitivity suggests that PHe dates will typically record emplacement rather than postemplacement processes. ZHe and PHe geochronology can effectively date kimberlite emplacement and provide useful complements to existing techniques. Sixteen southern African kimberlites were dated using zircon and/or perovskite (U‐Th)/He geochronology (U‐Th)/He of xenocrystic zircon can date kimberlite eruption if zircon are reset during eruption or resided at >200°C prior to entrainment Perovskite (U‐Th)/He is effective for kimberlite dating and has a higher He closure temperature than zircon
ISSN:1525-2027
1525-2027
DOI:10.1002/2016GC006519