Copper and zinc isotope systematics of altered oceanic crust at IODP Site 1256 in the eastern equatorial Pacific

Huang, Junhua; Liu, Sheng‐Ao; Gao, Yongjun; Xiao, Yilin; Chen, Sha

doi:10.1002/2016jb013095

Cited by 60 publications

(51 citation statements)

References 76 publications

(207 reference statements)

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“…Analyses of in‐house and international reference standards processed with the studied peridotites and pyroxenites yield δ 66 Zn = 0.28 ± 0.03‰ (2SD, n = 60) for IRMM3702, δ 66 Zn = 0.31 ± 0.05‰ (2SD, n = 6) for BHVO‐2, 0.22 ± 0.05‰ (2SD, n = 8) for JP‐1, and 0.26 ± 0.04‰ for DTS‐2 (2SD, n = 4) (Table ). These values agree well within error with previously published values (Chen et al, , ; Doucet et al, ; Huang et al, ; Huang, Chen, et al, ; Huang, Zhang, et al, ; Moynier et al, ; Sossi et al, ; Wang et al, ). This, combined with consistent results for repeated analyses (Table ), assures the accuracy and precision of our Zn isotopic data.…”

Section: Methodssupporting

confidence: 92%

“…Nb/Nb* = Nb PM /(Th PM × La PM ) 0.5 , PM denotes primitive mantle normalization. Nb/Nb* and Sr isotopic data are taken from Hart et al (), and Zn isotopic data are taken from Huang et al () for altered lower (ALOC) and upper (AUOC) oceanic crust. Zinc isotopic data for deep‐sea sediments are taken from Maréchal et al (), Bentahila et al (), and Little et al ().…”

Section: Discussionmentioning

confidence: 99%

“…Zinc isotopes can be significantly fractionated during continental weathering, carbonate and sulfide precipitation, and fluid‐rock reactions (e.g., Albarède, ; Moynier et al, ). These processes cause ~2.0‰ fractionation in δ 66 Zn (δ 66 Zn = [( 66 Zn/ 64 Zn) sample /( 66 Zn/ 64 Zn) JMC Lyon − 1] × 1000‰) of potential recycling components in subduction zones (e.g., sediments, altered oceanic crust, and serpentinite; Bentahila et al, ; Huang et al, ; Little et al, , ; Maréchal et al, ; Pichat et al, ; Pons et al, , ). The variable δ 66 Zn of recycling components compared to the relatively uniform δ 66 Zn of the normal mantle (0.16 ± 0.06‰, Sossi et al, ) highlights the potential use of Zn isotopes to trace crustal recycling and crust‐mantle interaction (Liu et al, ; Wang et al, ).…”

Section: Introductionmentioning

confidence: 99%

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Mantle Zn Isotopic Heterogeneity Caused by Melt‐Rock Reaction: Evidence From Fe‐Rich Peridotites and Pyroxenites From the Bohemian Massif, Central Europe

et al. 2019

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To investigate the effect of melt-rock reaction on Zn isotope fractionation and mantle Zn isotopic heterogeneity, we analyzed Zn isotopic compositions of peridotites, pyroxenites, and mineral separates from the Bohemian Massif, Central Europe. The Mg-lherzolites (Mg# = 90.9 to 89.1, FeO T = 7.9 to 9.0 wt %) are melting residues with only moderate metasomatism and have δ 66 Zn from 0.11 to 0.20‰. In contrast, the Fe-rich peridotites (Mg# = 88.2 to 80.3, FeO T = 10.0 to 14.5 wt %) and pyroxenites have larger ranges of δ 66 Zn from 0.11 to 0.31‰ and −0.33 to 0.42‰, respectively. Large disequilibrium intermineral Zn isotope fractionation occurs in the Fe-rich peridotites and pyroxenites with Δ 66 Zn Opx-Ol = −0.50‰, Δ 66 Zn Grt-Ol = −0.55 to −0.39‰, Δ 66 Zn Grt-Opx = −0.28 to −0.05‰, and Δ 66 Zn Grt-Cpx = −0.50 to 0.12‰. Combined with their low SiO 2 contents and radiogenic Sr-Nd-Os isotopic compositions, the high δ 66 Zn of the Fe-rich peridotites is attributed to reaction between Mg-lherzolites and percolating SiO 2 -undersaturated basaltic melts that incorporated isotopically heavy crustal components. Crystallization of the isotopically heavy percolating melts migrating through the lithospheric mantle yield the high-δ 66 Zn pyroxenites. The low δ 66 Zn of the pyroxenites and large intermineral Zn isotopic disequilibrium may result from kinetic Zn isotope fractionation during melt-rock reaction. Collectively, these observations indicate that melt-rock reaction can cause intermineral Zn isotopic disequilibrium and significant Zn isotopic heterogeneity in the mantle. This study thus highlights the potential use of Zn isotopes to trace melt-rock reaction events in the mantle.

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Section: Methodssupporting

confidence: 92%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Mantle Zn Isotopic Heterogeneity Caused by Melt‐Rock Reaction: Evidence From Fe‐Rich Peridotites and Pyroxenites From the Bohemian Massif, Central Europe

et al. 2019

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“…( 87/86 Sr AOC = 0.70458, Staudigel et al, 1995). Nonetheless, this process does not alter its Nd and Zn isotope composition ( 143/ 144 Nd AOC = 0.51308; δ 66 Zn AOC = +0.27 ± 0.01‰, Staudigel et al, 1995;Huang et al, 2016). Consequently, we argue that MORB-eclogite cannot account for the extreme Zn enrichment and global trends between Zn and Zn-Sr-Nd isotopes in oceanic basalts.…”

Section: Morb-type Oceanic Crust Recyclingmentioning

confidence: 72%

Mantle heterogeneity through Zn systematics in oceanic basalts: Evidence for a deep carbon cycling

Beunon

Mattielli

Doucet

et al. 2020

Earth-Science Reviews

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Subduction at convergent margins introduces a range of sedimentary and crustal materials into the mantle, providing the most dominant form of heterogeneity in the source of oceanic basalts. Yet, the relationship between geochemical variability and lithologic heterogeneities in the Earth's mantle remains controversial. In this paper, we comprehensively review Zn, δ 66 Zn and Sr-Nd isotope systematics in near-primary basalts erupted at mid-ocean ridges (MORB) and ocean islands (OIB) to help constrain the nature and proportion of the carbon (C) bearing slab-derived component in their mantle sources. We show that Zn elemental and isotopic composition of oceanic basalts differs according to their tectonic settings, increasing from MORB (Zn = 62 ± 10 to 73 ± 11 ppm; δ 66 Zn = +0.24 ± 0.01 to +0.31 ± 0.02‰) to OIB (Zn = 74 ± 9 to 124 ± 7 ppm; δ 66 Zn = +0.21 ± 0.07 to +0.40 ± 0.04‰). Unlike MORB, the high Zn and δ 66 Zn recorded in OIB cannot be explained by partial melting of a fertile peridotite mantle source only. Importantly, global correlations between Zn content and Sr-Nd isotopes in oceanic basalts suggest that the Zn enrichment in OIB is inherited from a recycled component in their mantle source rather than melting processes. We demonstrate that involvement of neither typical MORB-like oceanic crust nor subducted sediments can achieve the whole range of Zn composition in OIB. Instead, addition of ≤6% C-bearing oceanic crust to a fertile peridotite mantle fully resolves the Zn heterogeneity of OIB, both in terms of magnitude of Zn enrichment and global trends with Sr-Nd isotopes. Such scenario is corroborated by the elevated δ 66 Zn of OIB relative to MORB and mantle peridotites, reflecting the contribution of isotopically heavy C-bearing phases (δ 66 Zn = +0.91 ± 0.24‰) to the mantle source (δ 66 Zn = +0.16 ± 0.06‰). Our study thus emphasizes the use of Zn and δ 66 Zn systematics to track the nature and origin of mantle carbon, highlighting the role of subduction in the deep carbon cycle. Finally, the positive correlation between Zn content and temperature of magma generation of oceanic basalts suggests that hotter mantle plumes are more likely to carry a higher proportion of dense C-bearing eclogite. Zinc systematics therefore may provide evidence that the presence of heterogeneous domains in the source of OIB is, at least partly, linked to plume thermal buoyancy, bringing new insights into mantle dynamics.

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“…Recently Zn isotopes have been shown to be sensitive to mantle partial melting [ Doucet et al ., ; Wang et al ., ] and igneous differentiation [ Chen et al ., ], but owing to the complex metasomatic and metamorphic history of the studied samples, coupled with the lack of a comprehensive study of Zn isotopes in global MORB and oceanic gabbros, it is difficult to conclude if the variations in Zn isotope composition observed here reflect primary magmatic process or modification by late stage alteration and metasomatic processes. While it has previously been stated that the process of low‐temperature seafloor alteration of the upper, basaltic oceanic lithosphere has little effect on Zn isotopes, the same study demonstrated that high‐temperature (>350°C) hydrothermal circulation and complexing of light Zn isotopes in hydrothermal fluids could drive the Zn isotope composition toward heavier δ 66 Zn values in the gabbroic portion of the oceanic lithosphere [ Huang et al ., ]. This observation could be invoked to explain the range of δ 66 Zn values observed in the Zermatt and Queyras metagabbros, but as the samples now preserve a subduction‐related, Alpine overprint to their mineralogy it is not possible to unambiguously conclude on the effect of seafloor hydrothermal activity on the Zn isotope compositions of these rocks.…”

Section: Discussionmentioning

confidence: 99%

The behavior of iron and zinc stable isotopes accompanying the subduction of mafic oceanic crust: A case study from Western Alpine ophiolites

Inglis

Debret

Burton

et al. 2017

Geochem Geophys Geosyst

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Arc lavas display elevated Fe 31 /RFe ratios relative to MORB. One mechanism to explain this is the mobilization and transfer of oxidized or oxidizing components from the subducting slab to the mantle wedge. Here we use iron and zinc isotopes, which are fractionated upon complexation by sulfide, chloride, and carbonate ligands, to remark on the chemistry and oxidation state of fluids released during prograde metamorphism of subducted oceanic crust. We present data for metagabbros and metabasalts from the Chenaillet massif, Queyras complex, and the Zermatt-Saas ophiolite (Western European Alps), which have been metamorphosed at typical subduction zone P-T conditions and preserve their prograde metamorphic history. There is no systematic, detectable fractionation of either Fe or Zn isotopes across metamorphic facies, rather the isotope composition of the eclogites overlaps with published data for MORB. The lack of resolvable Fe isotope fractionation with increasing prograde metamorphism likely reflects the mass balance of the system, and in this scenario Fe mobility is not traceable with Fe isotopes. Given that Zn isotopes are fractionated by S-bearing and C-bearing fluids, this suggests that relatively small amounts of Zn are mobilized from the mafic lithologies in within these types of dehydration fluids. Conversely, metagabbros from the Queyras that are in proximity to metasediments display a significant Fe isotope fractionation. The covariation of d 56 Fe of these samples with selected fluid mobile elements suggests the infiltration of sediment derived fluids with an isotopically light signature during subduction.

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Copper and zinc isotope systematics of altered oceanic crust at IODP Site 1256 in the eastern equatorial Pacific

Cited by 60 publications

References 76 publications

Mantle Zn Isotopic Heterogeneity Caused by Melt‐Rock Reaction: Evidence From Fe‐Rich Peridotites and Pyroxenites From the Bohemian Massif, Central Europe

Mantle Zn Isotopic Heterogeneity Caused by Melt‐Rock Reaction: Evidence From Fe‐Rich Peridotites and Pyroxenites From the Bohemian Massif, Central Europe

Mantle heterogeneity through Zn systematics in oceanic basalts: Evidence for a deep carbon cycling

The behavior of iron and zinc stable isotopes accompanying the subduction of mafic oceanic crust: A case study from Western Alpine ophiolites

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