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Isotopic evidence for Late Cretaceous plume–ridge interaction at the Hawaiian hotspot

Randall A. Keller (), Martin R. Fisk and William M. White
Additional contact information
Randall A. Keller: College of Oceanic and Atmospheric Sciences, Oregon State University
Martin R. Fisk: College of Oceanic and Atmospheric Sciences, Oregon State University
William M. White: Cornell University

Nature, 2000, vol. 405, issue 6787, 673-676

Abstract: Abstract When a mantle plume interacts with a mid-ocean ridge, both are noticeably affected. The mid-ocean ridge can display anomalously shallow bathymetry, excess volcanism, thickened crust, asymmetric sea-floor spreading and a plume component in the composition of the ridge basalts1,2,3,4. The hotspot-related volcanism can be drawn closer to the ridge, and its geochemical composition can also be affected3,5,6,7. Here we present Sr–Nd–Pb isotopic analyses of samples from the next-to-oldest seamount in the Hawaiian hotspot track, the Detroit seamount at 51° N, which show that, 81 Myr ago, the Hawaiian hotspot produced volcanism with an isotopic signature indistinguishable from mid-ocean ridge basalt. This composition is unprecedented in the known volcanism from the Hawaiian hotspot, but is consistent with the interpretation from plate reconstructions8 that the hotspot was located close to a mid-ocean ridge about 80 Myr ago. As the rising mantle plume encountered the hot, low-viscosity asthenosphere and hot, thin lithosphere near the spreading centre, it appears to have entrained enough of the isotopically depleted upper mantle to overwhelm the chemical characteristics of the plume itself. The Hawaiian hotspot thus joins the growing list of hotspots that have interacted with a rift early in their history.

Date: 2000
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DOI: 10.1038/35015057

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