The intrinsic nature of antigorite breakdown at 3 GPa: Experimental constraints on redox conditions of serpentinite dehydration in subduction zones

Maurice, Juliette; Bolfan-Casanova, Nathalie; Demouchy, Sylvie; Chauvigne, Paul; Schiavi, Federica; Debret, Baptiste

doi:10.1007/s00410-020-01731-y

Cited by 26 publications

(30 citation statements)

References 85 publications

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“…1A). These results agree well with published literature values (Ulmer and Trommsdorff 1995;Wunder and Schreyer 1997;Bromiley and Pawley 2003;Maurice et al 2020), and in this system antigorite breaks down to form olivine, orthopyroxene, and fluid.…”

Section: Stability and Breakdown Of Antigoritesupporting

confidence: 93%

The stability of antigorite in subduction zones revisited: the effect of F on antigorite stability and its breakdown reactions at high pressures and high temperatures, with implications for the geochemical cycles of halogens

Flemetakis

Tiraboschi

Rohrbach

et al. 2022

Contrib Mineral Petrol

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We present new experimental data on the effect of F on the stability of antigorite and its breakdown products at high pressures (2–6 GPa) and high temperatures (570–850 °C). The experiments show that F does not affect the stability of antigorite, but addition of F to the system affects which minerals are formed when antigorite breaks down. In a F-free system and in a system with intermediate F contents (2 wt% F), antigorite breaks down to olivine and orthopyroxene, but in a F-rich system (5 wt% F), antigorite breaks down to other hydrous and F-bearing mineral assemblages which include chlorite, clinohumite and humite-group minerals (HGM). Since the latter mineral phases are stable at higher pressures and temperatures, and contain more F than antigorite, significant amounts of F and potentially other halogens can be retained in the subducting slab and transported deep into the mantle and possibly even into the Earth’s transition zone.

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Section: Stability and Breakdown Of Antigoritesupporting

confidence: 93%

The stability of antigorite in subduction zones revisited: the effect of F on antigorite stability and its breakdown reactions at high pressures and high temperatures, with implications for the geochemical cycles of halogens

Flemetakis

Tiraboschi

Rohrbach

et al. 2022

Contrib Mineral Petrol

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“…If metamorphism and deserpentinization does result in a decrease of Fe(III)/ΣFe, the reduction of Fe(III) to Fe(II) would require the formation of an oxidized component such as SO x or CO x . This interpretation, while still debated, would suggest that serpentinite dehydration has the potential to release oxidizing fluids with an isotopically heavy  11 B signature (15)(16)(17)23).…”

Section: Cu Enrichment During Arc Magma Evolution Promoted By 11 B-rich Slab Fluidsmentioning

confidence: 99%

“…Evans and Frost (18) elaborated on a variety of processes that may affect the redox budget of subducted serpentinites and, thereby, the capacity of serpentinite-derived fluids to oxidize subarc mantle. While some studies conclude that fluids released by serpentine dehydration are sufficiently oxidized to affect the redox budget of arc magmas (15)(16)(17), others suggest that these fluids may be notably less oxidized (42). Serpentinite within the subducting plate has isotopically heavy B ( 11 B up to +40‰) and is a possible source of 11 B in arc magmas (37).…”

Section: Cu Enrichment During Arc Magma Evolution Promoted By 11 B-rich Slab Fluidsmentioning

confidence: 99%

“…However, the dehydration of subducted serpentinite has been increasingly recognized as an important source of volatiles (e.g., water, sulfur, and halogens) in the subarc mantle (10)(11)(12). Like AOC (7,13), breakdown of oxidized serpentinites can produce highly oxidizing fluids (14)(15)(16)(17)(18), which may have an important influence on the f O2 of arc magmas. Boron (B) isotopes ( 11 B = [( 11 B/ 10 B) Sample /( 11 B/ 10 B) SRM951 -1]*1000) are a powerful tool for tracing the presence of serpentinite-derived fluids, as 11 B is depleted in the upper mantle [B < 0.1 parts per million (ppm);  11 B = −10 to −7‰] but is extremely enriched in serpentinite (up to 100 ppm B;  11 B up to +40‰) (19).…”

Section: Introductionmentioning

confidence: 99%

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Serpentinite-derived slab fluids control the oxidation state of the subarc mantle

et al. 2021

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Recent geochemical evidence confirms the oxidized nature of arc magmas, but the underlying processes that regulate the redox state of the subarc mantle remain yet to be determined. We established a link between deep subduction-related fluids derived from dehydration of serpentinite ± altered oceanic crust (AOC) using B isotopes and B/Nb as fluid proxies, and the oxidized nature of arc magmas as indicated by Cu enrichment during magma evolution and V/Yb. Our results suggest that arc magmas derived from source regions influenced by a greater serpentinite (±AOC) fluid component record higher oxygen fugacity. The incorporation of this component into the subarc mantle is controlled by the subduction system's thermodynamic conditions and geometry. Our results suggest that the redox state of the subarc mantle is not homogeneous globally: Primitive arc magmas associated with flat, warm subduction are less oxidized overall than those generated in steep, cold subduction zones.

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“…Info). Furthermore, the poorly constrained effect of some minor elements (Al, Fe) and the unknown prevailing oxidation state of ultramafic rocks under high-PT conditions [20,21] preclude proper petrological modeling of subducted ultramafic rocks. Consequently, experimental and modeled phase diagrams often differ at pressures above 6 GPa ( Fig.…”

mentioning

confidence: 99%

Sea-level stability over geologic time owing to limited deep subduction of hydrated mantle

Cerpa¹,

Arcay²,

Padrón‐Navarta³

2022

Preprint

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The presence of liquid water makes our planet unique. Its budget over geological timescales, i.e., the long-term global sea level, depends on the balance of water exchanges between the Earth's mantle and the surface through both volcanism (mantle degassing) and subduction of hydrous minerals (mantle regassing). Current estimates of subduction water fluxes predict that regassing exceeds degassing by 50%, thereby suggesting a sea-level drop of several hundred meters in the last 540 Ma. The models further suggest that the subducting crust is the main supplier of water to the deep mantle. In contrast, various observations advocate for a near-steady state long term sea level and report voluminous water subduction via the hydrated lithospheric mantle. We have revised the subduction water flux calculations using constraints from recent experimental data on natural peridotites under high-pressure and high-temperature conditions. Our novel thermopetrological models show that the present-day global water retention in subducting plates beyond mid-upper mantle depths barely exceeds the estimations of mantle degassing, and thus quantitatively support the steady-state sea level scenario over geological times. Furthermore, the limited mantle regassing is solely driven by the lithospheric mantle of the coldest subduction zones.

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The intrinsic nature of antigorite breakdown at 3 GPa: Experimental constraints on redox conditions of serpentinite dehydration in subduction zones

Cited by 26 publications

References 85 publications

The stability of antigorite in subduction zones revisited: the effect of F on antigorite stability and its breakdown reactions at high pressures and high temperatures, with implications for the geochemical cycles of halogens

The stability of antigorite in subduction zones revisited: the effect of F on antigorite stability and its breakdown reactions at high pressures and high temperatures, with implications for the geochemical cycles of halogens

Serpentinite-derived slab fluids control the oxidation state of the subarc mantle

Sea-level stability over geologic time owing to limited deep subduction of hydrated mantle

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