Recycled ancient ghost carbonate in the Pitcairn mantle plume

Recycled ancient ghost carbonate in the Pitcairn mantle plume

The extreme Sr, Nd, Hf, and Pb isotopic compositions found in Pitcairn Island basalts have been labeled enriched mantle 1 (EM1), characterizing them as one of the isotopic mantle end members. The EM1 origin has been vigorously debated for over 25 years, with interpretations ranging from delaminated...

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Veröffentlicht in:Proceedings of the National Academy of Sciences - PNAS 2018-08, Vol.115 (35), p.8682-8687
Hauptverfasser: Wang, Xiao-Jun, Chen, Li-Hui, Hofmann, Albrecht W., Hanyu, Takeshi, Kawabata, Hiroshi, Zhong, Yuan, Xie, Lie-Wen, Shi, Jin-Hua, Miyazaki, Takashi, Hirahara, Yuka, Takahashi, Toshiro, Senda, Ryoko, Chang, Qing, Vaglarov, Bogdan S., Kimura, Jun-Ichi
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Basalt
Carbonates
Composition
Continental crust
Extreme values
Fractionation
Isotopes
Lava
Lead
Lithosphere
Lower mantle
Magnesium
Mantle
Melts
Oceanic crust
Pelagic sediments
Physical Sciences
Polls & surveys
Sediments
Silicates
Sulfur
Sulfur isotopes
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container_end_page 8687
container_issue 35
container_start_page 8682
container_title Proceedings of the National Academy of Sciences - PNAS
container_volume 115
creator Wang, Xiao-Jun
Chen, Li-Hui
Hofmann, Albrecht W.
Hanyu, Takeshi
Kawabata, Hiroshi
Zhong, Yuan
Xie, Lie-Wen
Shi, Jin-Hua
Miyazaki, Takashi
Hirahara, Yuka
Takahashi, Toshiro
Senda, Ryoko
Chang, Qing
Vaglarov, Bogdan S.
Kimura, Jun-Ichi
description The extreme Sr, Nd, Hf, and Pb isotopic compositions found in Pitcairn Island basalts have been labeled enriched mantle 1 (EM1), characterizing them as one of the isotopic mantle end members. The EM1 origin has been vigorously debated for over 25 years, with interpretations ranging from delaminated subcontinental lithosphere, to recycled lower continental crust, to recycled oceanic crust carrying ancient pelagic sediments, all of which may potentially generate the requisite radiogenic isotopic composition. Here we find that δ26Mg ratios in Pitcairn EM1 basalts are significantly lower than in normal mantle and are the lowest values so far recorded in oceanic basalts. A global survey of Mg isotopic compositions of potentially recycled components shows that marine carbonates constitute the most common and typical reservoir invariably characterized by extremely low δ26Mg values. We therefore infer that the subnormal δ26Mg of the Pitcairn EM1 component originates from subducted marine carbonates. This, combined with previously published evidence showing exceptionally unradiogenic Pb as well as sulfur isotopes affected by mass-independent fractionation, suggests that the Pitcairn EM1 component is most likely derived from late Archean subducted carbonate-bearing sediments. However, the low Ca/Al ratios of Pitcairn lavas are inconsistent with experimental evidence showing high Ca/Al ratios in melts derived from carbonate-bearing mantle sources. We suggest that carbonate–silicate reactions in the late Archean subducted sediments exhausted the carbonates, but the isotopically light magnesium of the carbonate was incorporated in the silicates, which then entered the lower mantle and ultimately became the Pitcairn plume source.
doi_str_mv 10.1073/pnas.1719570115
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The EM1 origin has been vigorously debated for over 25 years, with interpretations ranging from delaminated subcontinental lithosphere, to recycled lower continental crust, to recycled oceanic crust carrying ancient pelagic sediments, all of which may potentially generate the requisite radiogenic isotopic composition. Here we find that δ26Mg ratios in Pitcairn EM1 basalts are significantly lower than in normal mantle and are the lowest values so far recorded in oceanic basalts. A global survey of Mg isotopic compositions of potentially recycled components shows that marine carbonates constitute the most common and typical reservoir invariably characterized by extremely low δ26Mg values. We therefore infer that the subnormal δ26Mg of the Pitcairn EM1 component originates from subducted marine carbonates. 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subjects Basalt
Carbonates
Composition
Continental crust
Extreme values
Fractionation
Isotopes
Lava
Lead
Lithosphere
Lower mantle
Magnesium
Mantle
Melts
Oceanic crust
Pelagic sediments
Physical Sciences
Polls & surveys
Sediments
Silicates
Sulfur
Sulfur isotopes
title Recycled ancient ghost carbonate in the Pitcairn mantle plume
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