Volatile cycling of <scp>H<sub>2</sub>O</scp>, <scp>CO</scp><sub>2</sub>, <scp>F</scp>, and <scp>C</scp>l in the <scp>HIMU</scp> mantle: A new window provided by melt inclusions from oceanic hot spot lavas at <scp>M</scp>angaia, <scp>C</scp>ook <scp>I</scp>slands

Cabral, Rita A.; Jackson, Matthew G.; Koga, Kenneth T.; Rose-Koga, Estelle; Hauri, E. H.; Whitehouse, Martin J.; Price, Allison; Day, James M.D.; Shimizu, Nobumichi; Kelley, K. A.

doi:10.1002/2014gc005473

Cited by 69 publications

(99 citation statements)

References 155 publications

(441 reference statements)

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“…H 2 O, Ce content, and H 2 O/Ce are from these literatures. PM: McDonough and Sun () and Dixon and Clague (); DMM: Workman and Hart () and Salters and Stracke (); EM I: Kendrick et al (); EM II: Workman et al () and Kendrick et al (); HIMU: Cabral et al ().…”

Section: Discussionmentioning

confidence: 99%

Variations in the H₂O Content and H₂O/Ce Ratio of Mantle Pyroxenites: Implications for Enriched Components in the Mantle

Hao

Coltorti

et al. 2018

JGR Solid Earth

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Mantle pyroxenite xenoliths were collected from Hannuoba, East China, and investigated for their H2O content and trace element contents, with particular regard to the H2O/Ce ratio. The pyroxenites were divided into three groups: Cr‐pyroxenites, Al‐pyroxenites, and garnet pyroxenites. The H2O contents and H2O/Ce ratios of the pyroxenites in this study showed much wider ranges than those previously reported for the whole rock pyroxenites. The Cr‐pyroxenites had an H2O content ranging from 23 to 339 ppm and an H2O/Ce ratio between 32 and 212; the Al‐pyroxenites had an H2O content ranging from 42 to 106 ppm and an H2O/Ce ratio between 1 and 22, and the garnet pyroxenites had an H2O content ranging from 37 to 69 ppm and an H2O/Ce ratio between 5 and 54. These systematic variations in the H2O contents and H2O/Ce ratios for the Hannuoba pyroxenites are associated with their origins. Both the H2O content and H2O/Ce ratio of the Al‐pyroxenites were low compared to those of Hawaiian pyroxenite, enriched mantle, and depleted MORB mantle sources. The high H2O content and H2O/Ce ratio of the melt equilibrated with the Cr‐pyroxenites indicate that a water‐rich component was involved in its formation. Their large variations in the H2O contents and H2O/Ce ratios may indicate that pyroxenites are essential enriched components in the sources of continental basalts.

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Section: Discussionmentioning

confidence: 99%

Variations in the H₂O Content and H₂O/Ce Ratio of Mantle Pyroxenites: Implications for Enriched Components in the Mantle

Hao

Coltorti

et al. 2018

JGR Solid Earth

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“…Specifically, the EM‐I type hotspot lavas of the Pitcairn and Koolau end‐members in Hawaii exhibit H 2 O/Ce values of ~80 and ~111, respectively [ Kendrick et al , ; Dixon and Clague , ], while the EM‐II type lavas of Samoa and Society exhibit H 2 O/Ce values of ~50–80 [ Workman et al , ; Kendrick et al , , ]. In contrast, the HIMU type lavas have a higher H 2 O/Ce of ~200, and FOZO type components in the Atlantic and Pacific plume‐influenced MORB have H 2 O/Ce values of >250 and ~210, respectively [ Dixon et al , ; Métrich et al , ; Cabral et al , ]. Thus, it is clear that the EM‐type lavas have the lowest H 2 O/Ce ratios.…”

Section: Discussionmentioning

confidence: 99%

Recycled oceanic crust and marine sediment in the source of alkali basalts in Shandong, eastern China: Evidence from magma water content and oxygen isotopes

et al. 2015

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The magma water contents and cpx δ18O values in alkali basalts from the Fuyanyshan (FYS) volcano in Shandong, eastern China, were investigated by an inverse calculation based on the water content of clinopyroxene (cpx) phenocrysts, the ivAlcpx‐dependent water partitioning coefficient Dwaternormalcnormalpnormalxtrue/melt, and secondary ion mass spectrometer, respectively. The calculated water content (H2O wt.) of magma ranges from 0.58% to 3.89%. It positively correlates with heavy rare earth element concentrations and bulk rock 87Sr/86Sr ratios, and it negatively correlates with Nb/U ratios. However, it is not correlated with bulk Mg# (Mg# = 100 × Mg / (Mg + Fe)) and (La/Yb)n (n represents primitive mantle normalization). Combined with the rather homogenous distribution of water content within cpx grains, these correlations indicate that the water variations among different samples represent the original magma signature, rather than results of a shallow process, such as degassing and diffusion. The δ18O of cpx phenocrysts varies from 3.6‰ to 6.3‰ (±0.5‰, 2SD), which may be best explained by the involvement of components from the lower and upper oceanic crust with marine sediments within the mantle source. The H2O/Ce ratios of the calculated melts range from 113 to 696 and form a positive trend with bulk rock 87Sr/86Sr, which cannot be explained by the recycled Sulu eclogite or by the metasomatized lithospheric mantle. Our modeling calculation shows that the decoupling of εHf and εNd could be caused by the involvement of marine sediments. Combing the high Ba/Th ratios, positive Sr spikes, and low Ce/Pb ratios for the Fuyanshan basalts, we suggest that the hydrous nature of the FYS basalts was derived from the hydrous mantle transition zone with ancient sediments.

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“…The lack of fresh, deeply dredged HIMU glass has been an impediment to developing a more complete understanding of the HIMU mantle. The recovery of the glasses reported here is important because volatile budgets of the HIMU mantle are critical for the generation of melts of this end‐member [ Jackson and Dasgupta , ; Dasgupta et al ., ; Gerbode and Dasgupta , ; Mallik and Dasgupta , ], and the volatile budgets of HIMU lavas may provide clues to how volatiles are cycled through the mantle, from subduction zones to hotspots [ Cabral et al ., ]. During residence on the seafloor, the uppermost portion of oceanic crust undergoes low‐temperature alteration and incorporation of volatiles (including several weight percent H 2 O and CO 2 ) [ Staudigel et al ., ; Alt and Teagle , ; Bach et al ., ; Wallmann , ; Dixon et al ., ; Gillis and Coogan , ].…”

Section: Introductionmentioning

confidence: 99%

“…For example, subducted upper continental crust is suggested to give rise to the EM2 mantle end‐member [ White and Hofmann , ; Jackson et al ., ; Workman et al ., ], but the origin of EM1 is not as well understood [ Weaver , ; Eiler et al ., ; Gasperini et al ., ; Eisele et al ., ; Honda and Woodhead , ; Geldmacher et al ., ; Salters and Sachi‐Kocher , ; Collerson et al ., ; Hart , ; Konter and Becker , ; Garapic et al ., ]. The HIMU mantle end‐member is characterized by the most radiogenic Pb‐isotopic compositions in the oceanic mantle, and is thought to originate from recycling of ancient subducted oceanic crust [e.g., Chase , ; Hofmann and White , ; Zindler et al ., ; Nakamura and Tatsumoto , ; Dupuy et al ., ; Graham et al ., ; Hauri and Hart , ; Hémond et al ., ; Roy‐Barman and Allègre , ; Woodhead , ; Hanyu and Kaneoka , ; Kogiso et al ., ; Salters and White , ; Schiano et al ., ; Lassiter et al ., ; Stracke et al ., ; Stroncik and Haase , ; Kelley et al ., ; Nishio et al ., ; Chan et al ., ; Parai et al ., ; Day et al ., ; John et al ., ; Hanyu et al ., ; Kawabata et al ., ; Salters et al ., ; Krienitz et al ., ; Cabral et al ., ]. Alternative mechanisms for generating the HIMU mantle have been proposed, including metasomatism, melting of lower mantle phases, and carbonate recycling [ Niu and O'Hara , ; Pilet et al ., ; Collerson et al ., ; Castillo , ].…”

Section: Introductionmentioning

confidence: 99%

Deeply dredged submarine HIMU glasses from the Tuvalu Islands, Polynesia: Implications for volatile budgets of recycled oceanic crust

Jackson

Koga

Price

et al. 2015

Geochem Geophys Geosyst

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Pb). Until now, deeply dredged submarine HIMU glasses have not been available, which has inhibited complete geochemical (in particular, volatile element) characterization of the HIMU mantle. We report major, trace and volatile element abundances in a suite of deeply dredged glasses from the Tuvalu Islands. Three Tuvalu glasses with the most extreme HIMU signatures have F/Nd ratios (35.6 6 3.6) that are higher than the ratio (21) for global OIB and MORB, consistent with elevated F/Nd ratios in end-member HIMU Mangaia melt inclusions. The Tuvalu glasses with the most extreme HIMU composition have Cl/K (0.11-0.12), Br/Cl (0.0024), and I/Cl (5-6 3 10 25 ) ratios that preclude significant assimilation of seawater-derived Cl. The new HIMU glasses that are least degassed for H 2 O have low H 2 O/Ce ratios (75-84), similar to ratios identified in end-member OIB glasses with EM1 and EM2 signatures, but significantly lower than H 2 O/Ce ratios (119-245) previously measured in melt inclusions from Mangaia. CO 2 -H 2 O equilibrium solubility models suggest that these HIMU glasses (recovered in two different dredges at 2500-3600 m water depth) have eruption pressures of 295-400 bars. We argue that degassing is unlikely to significantly reduce the primary melt H 2 O. Thus, the lower H 2 O/Ce in the HIMU Tuvalu glasses is a mantle signature. We explore oceanic crust recycling as the origin of the low H 2 O/Ce (50-80) in the EM1, EM2, and HIMU mantle domains.

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Volatile cycling of H₂O, CO₂, F, and Cl in the HIMU mantle: A new window provided by melt inclusions from oceanic hot spot lavas at Mangaia, Cook Islands

Cited by 69 publications

References 155 publications

Variations in the H₂O Content and H₂O/Ce Ratio of Mantle Pyroxenites: Implications for Enriched Components in the Mantle

Variations in the H₂O Content and H₂O/Ce Ratio of Mantle Pyroxenites: Implications for Enriched Components in the Mantle

Recycled oceanic crust and marine sediment in the source of alkali basalts in Shandong, eastern China: Evidence from magma water content and oxygen isotopes

Deeply dredged submarine HIMU glasses from the Tuvalu Islands, Polynesia: Implications for volatile budgets of recycled oceanic crust

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Volatile cycling of H2O, CO2, F, and Cl in the HIMU mantle: A new window provided by melt inclusions from oceanic hot spot lavas at Mangaia, Cook Islands

Cited by 69 publications

References 155 publications

Variations in the H2O Content and H2O/Ce Ratio of Mantle Pyroxenites: Implications for Enriched Components in the Mantle

Variations in the H2O Content and H2O/Ce Ratio of Mantle Pyroxenites: Implications for Enriched Components in the Mantle

Recycled oceanic crust and marine sediment in the source of alkali basalts in Shandong, eastern China: Evidence from magma water content and oxygen isotopes

Deeply dredged submarine HIMU glasses from the Tuvalu Islands, Polynesia: Implications for volatile budgets of recycled oceanic crust

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Volatile cycling of H₂O, CO₂, F, and Cl in the HIMU mantle: A new window provided by melt inclusions from oceanic hot spot lavas at Mangaia, Cook Islands

Variations in the H₂O Content and H₂O/Ce Ratio of Mantle Pyroxenites: Implications for Enriched Components in the Mantle

Variations in the H₂O Content and H₂O/Ce Ratio of Mantle Pyroxenites: Implications for Enriched Components in the Mantle