No significant boron in the hydrated mantle of most subducting slabs

McCaig, A. M.; Titarenko, Sofya; Savov, Ivan P.; Cliff, R. A.; Banks, David; Boyce, Adrian J.; Agostini, Samuele

doi:10.1038/s41467-018-07064-6

Cited by 26 publications

(14 citation statements)

References 77 publications

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“…Serpentinite breakdown has long been believed to play a crucial role in element transfer in subduction zones 8 , 15 , 16 . However, whether this serpentinite formed in the downgoing oceanic lithosphere or in the fore-arc mantle has been difficult to resolve 27 , 28 . Mo isotopes may help distinguish the respective roles of these two serpentinite sources.…”

Section: Discussionmentioning

confidence: 99%

“…While the importance of serpentinite subduction in the subduction zone chemical cycle is now widely acknowledged, it remains a formidable task to discriminate among these competing models. Which serpentinite sources are responsible, and how they work in the subduction zones are still unclear 27 , 28 . Molybdenum (Mo) is mobile in fluids, like Pb and Ba, but it can also be partially retained in rutile during slab dehydration or melting.…”

Section: Introductionmentioning

confidence: 99%

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Molybdenum isotopes unmask slab dehydration and melting beneath the Mariana arc

Zhao

et al. 2021

Nat Commun

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How serpentinites in the forearc mantle and subducted lithosphere become involved in enriching the subarc mantle source of arc magmas is controversial. Here we report molybdenum isotopes for primitive submarine lavas and serpentinites from active volcanoes and serpentinite mud volcanoes in the Mariana arc. These data, in combination with radiogenic isotopes and elemental ratios, allow development of a model whereby shallow, partially serpentinized and subducted forearc mantle transfers fluid and melt from the subducted slab into the subarc mantle. These entrained forearc mantle fragments are further metasomatized by slab fluids/melts derived from the dehydration of serpentinites in the subducted lithospheric slab. Multistage breakdown of serpentinites in the subduction channel ultimately releases fluids/melts that trigger Mariana volcanic front volcanism. Serpentinites dragged down from the forearc mantle are likely exhausted at >200 km depth, after which slab-derived serpentinites are responsible for generating slab melts.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Molybdenum isotopes unmask slab dehydration and melting beneath the Mariana arc

Zhao

et al. 2021

Nat Commun

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“…Thus, the only plausible reason for B enrichment in the primary mantle minerals is supply of boron as the rocks still resided at mantle depth, providing for high enough temperatures to facilitate re‐equilibration. A possible scenario is that B‐enriched fluid was liberated by dehydration of abyssal serpentinite in a subducting footwall plate, which may contain up to 200 ppm B (Harvey et al., 2014; McCaig, 2018; Pabst et al., 2011; Vils et al., 2008). The released fluid, in turn, migrated to the overlying mantle wedge and re‐equilibrated with the mantle minerals.…”

Section: Discussionmentioning

confidence: 99%

Water in the Supra‐Subduction‐Zone Mantle of the Mariana‐Izu‐Bonin Forearc: Constraints From Peridotitic Orthopyroxene

Gose

Schmädicke

2021

Geochem Geophys Geosyst

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Orthopyroxene was analyzed as a proxy for water supra‐subduction‐zone peridotite by polarized infrared radiation. Samples from Conical and Torishima seamounts, Mariana‐Izu‐Bonin forearc (ODP‐Leg 125), have very similar average H2O contents of 215 ppm (range: 122–363 ppm; Conical) and 191 ppm (range: 116–292 ppm; Torishima). Conical peridotite equilibrated at lower temperature (760°C) and oxygen fugacity (ΔlogFMQ −0.65) than samples from Torishima (830°C; ΔlogFMQ +0.33). The degree of partial melting is almost identical for the two sites (18% and 20%). The H2O concentrations are considerably higher compared to samples from the Bismarck forearc (31–92 ppm; Tollan and Hermann, 2019). Instead, the average values resemble those of peridotitic orthopyroxene from MOR settings. The measured H2O contents by far exceed values expected for residual peridotite. This implies that secondary uptake of water must have occurred after melt‐extraction but prior to exhumation to shallow crustal levels. Most likely, re‐equilibration took place at c. 50 km depth. As indicated by elemental correlations and/or enhanced contents, the secondary fluid(s) must have been enriched in B, K, Li, and Sr. The boron contents of orthopyroxene are c. 10 times higher those in MOR samples. These findings suggest that peridotite from Conical and Torishima seamounts was presumably infiltrated by fluid generated by dehydration reactions in a subducting plate. The elemental spectrum points to two source lithologies: (i) serpentinite (liberation of B) and metasediments (liberation of K, Li, and Sr). The varying H2O contents point to heterogeneous fluid supply suggesting that fluid infiltration was not pervasive.

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“…Considering this close association with troctolites and an alteration texture typical for rodingitization, massive occurrence of clinopyroxene in the 400 °C experiment might provide an alternative low T formation hypothesis for this unique dyke lithology. Secondary clinopyroxene in association with altered troctolites has been reported before at Hess Deep where it was interpreted as a late high-grade (>360 °C) hydrothermal overprint of a preceding chlorite-prehnite alteration that occurred lower temperatures (200 °C -Gillis et al 2014;McCaig et al 2018).…”

mentioning

confidence: 70%

“…However, only few studies investigated the alteration of troctolitic rocks (Frost et al 2008;Beard et al 2009;Nakamura et al 2009;Nozaka et al 2017;McCaig et al 2018). Frost et al (2008) suggested that the troctolite alteration resembles a one-rock rodingitization, in which olivine represents the ultramafic and plagioclase the gabbroic component.…”

Section: Introductionmentioning

confidence: 99%

Hydrothermal troctolite alteration at 300 and 400 °C: Insights from flexible Au-reaction cell batch experimental investigations

Hansen,

Lissenberg,

Kahl

et al. 2022

American Mineralogist

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Troctolites are increasingly recognized as a common rock found in association with oceanic core complexes. They are similar to komatiite in composition and troctolite alteration hence may provide insight into H2 production on Early Earth. We investigated the hydrothermal alteration of olivine-rich troctolites in two batch experiments (300 °C, 400 °C and 40 MPa) by reacting forsteritic olivine and anorthite-rich plagioclase with salt solutions. The alteration process was evaluated based on concomitant fluid samples and solids retrieved upon termination of the experiments. In both experiments the initial rock powder was turned into a hard, compact mass through cementation by secondary phases.The heterogeneity of this mass was documented using µ-computed tomography and electron microscopy. Thermodynamic computations were conducted to determine the equilibrium phase assemblages and fluid compositions with increasing reaction turnover.Mineral zonation developed between the fast reacting, fluid dominated top portion of the solids and the more isolated portions at the bottom of the reaction cell. At 300 °C, the total This is the peer-reviewed, final accepted version for American Mineralogist, published by the Mineralogical Society of America.The published version is subject to change. Cite as Authors (Year) Title. American Mineralogist, in press.

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No significant boron in the hydrated mantle of most subducting slabs

Cited by 26 publications

References 77 publications

Molybdenum isotopes unmask slab dehydration and melting beneath the Mariana arc

Molybdenum isotopes unmask slab dehydration and melting beneath the Mariana arc

Water in the Supra‐Subduction‐Zone Mantle of the Mariana‐Izu‐Bonin Forearc: Constraints From Peridotitic Orthopyroxene

Hydrothermal troctolite alteration at 300 and 400 °C: Insights from flexible Au-reaction cell batch experimental investigations

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