The behavior of iron and zinc stable isotopes accompanying the subduction of mafic oceanic crust: A case study from <scp>W</scp>estern <scp>A</scp>lpine ophiolites

Inglis, Edward; Debret, Baptiste; Burton, Kevin W.; Millet, Marc-Alban; Pons, Marie-Laure; Dale, C. W.; Bouilhol, Pierre; Cooper, Matthew J.; Nowell, Geoff; McCoy-West, Alex J.; Williams, Helen M.

doi:10.1002/2016gc006735

Cited by 71 publications

(52 citation statements)

References 111 publications

(154 reference statements)

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“…Both geological standards are within error of reported average literature values of δ 66 Zn (0.25±0.08 for BCR-2, 0.29±0.06 for AGV2; Moynier et al, 2017). Our analyses of CP1 metasediments show that the obtained Zn isotope data (δ 66 Zn = -0.07±0.10 , δ 68 Zn = -0.17±0.11 ) are also in agreement with previously reported data (δ 66 Zn = 0.00±0.08 , Inglis et al, 2017). All data lie on the mass-dependent correlation line ( Fig.…”

Section: Terrestrial Standardssupporting

confidence: 92%

“…We have sampled multiple terrestrial standards with varying bulk compositions and with known Zn isotope signatures. Per standard, five samples were weighed (50-200 µg per sample) containing approximately 5-10 ng Zn each, from bulk powders of BCR-2 (USGS basalt), AGV2 (USGS andesite) and CP1 (metasediment from the Queyras Schiste lustrs Complex, Inglis et al, 2017). In addition, we have selected larger aliquots of BHVO-2 (USGS basalt) and CV chondrite NWA 12523 (5 mg), with totals of ∼600 ng Zn each.…”

Section: Methodsmentioning

confidence: 99%

“…Table 2). The shaded areas are (recommended) literature values for CP1 (purple, Inglis et al, 2017) and BHVO-2, BCR-2 and AGV2 (orange, Moynier et al, 2017). We note that literature only reports the δ 66 Zn values.…”

Section: Cut-off Matrix Elutionmentioning

confidence: 99%

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Zinc isotope analyses of singularly small samples (<5 ng Zn): Investigating chondrule-matrix complementarity in Leoville

Kooten

Moynier

2019

Geochimica et Cosmochimica Acta

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The potential complementarity between chondrules and matrix of chondrites, the Solar System's building blocks, is still a highly debated subject. Complementary superchrondritic compositions of chondrite matrices and subchondritic chondrules may point to formation of these components within the same reservoir or, alternatively, to mobilization of elements during secondary alteration on chondrite parent bodies. Zinc isotope fractionation through evaporation during chondrule formation may play an important role in identifying complementary relationships between chondrules and matrix and is additionally a mobile element during hydrothermal processes. In an effort to distinguish between primary Zn isotope fractionation during chondrule formation and secondary alteration, we here report the Zn isotope data of five chondrule cores, five corresponding igneous rims and two matrices of the relatively unaltered Leoville CV3.1 chondrite. The detail required for these analyses necessitated the development of an adjusted Zn isotope analyses protocol outlined in this study. This method allows for the measurement of 5 ng Zn fractions, for which we have analyzed the isotope composition with an external reproducibility of 120 ppm. We demonstrate that we measure primary Zn isotope signatures within the sampled fractions of Leoville, which show negative δ 66 Zn values for the chondrule cores (δ 66 Zn = -0.43±0.14 ), more positive values for the igneous rims (δ 66 Zn = -0.01±0.30 ) and chon-dritic values for the matrix (δ 66 Zn = 0.19±0.14 ). In combination with elemental compositions and petrology of these chondrite fractions, we argue that chondrule cores, igneous rims and matrix could have formed within the same reservoir in the protoplanetary disk. The required formation mechanism involves Zn isotope fractionation through sulfide loss during chondrule core formation and concurrent thermal processing of matrix material. Depleted olivine-bearing grains representing this processed matrix would have accreted to the depleted chondrule cores and subsequently reabsorbed material (including 66 Zn-rich) from a complementary volatile-rich gas, thereby forming the igneous rims. This would have allowed the rims to move towards an isotopically chondritic composition, similar to the non-processed matrix in Leoville. We note that Zn isotope analyses of components in other chondrites (f.e., CM, CO, EC) are necessary to identify if this complementarity relationship is generic or unique for each chondrite group. The development of a Zn isotope protocol for singularly small samples is a step forward in that direction.

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Section: Terrestrial Standardssupporting

confidence: 92%

Section: Methodsmentioning

confidence: 99%

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Zinc isotope analyses of singularly small samples (<5 ng Zn): Investigating chondrule-matrix complementarity in Leoville

Kooten

Moynier

2019

Geochimica et Cosmochimica Acta

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“…Melt extraction and mantle depletion processes at MORs and BABs with flux‐induced metasomatic enrichment of the mantle at ocean–ocean and ocean–continent convergent margins collectively attribute to the pervasive chemical heterogeneity in the asthenospheric mantle triggering magmatism of diverse compositions. A geochemically depleted asthenospheric mantle rendered by melt extraction episodes at mid‐oceanic ridge (MOR) systems and back‐arc basins (BAB) is re‐injected and replenished at ocean–ocean and ocean–continent subduction zones by hydration, metasomatism, and hybridization of asthenospheric mantle wedge through release of fluids, sediments, and melts from dehydration and melting of subducting oceanic slab, respectively (Brandl et al, ; Inglis et al, ; Masuda & Fryer, ). Magmas produced in mid‐oceanic ridge settings and island‐arc systems reflect distinct geochemical features that link respective magmatic processes and geodynamic conditions.…”

Section: Introductionmentioning

confidence: 99%

“…A geochemically depleted asthenospheric mantle rendered by melt extraction episodes at mid-oceanic ridge (MOR) systems and back-arc basins (BAB) is re-injected and replenished at ocean-ocean and oceancontinent subduction zones by hydration, metasomatism, and hybridization of asthenospheric mantle wedge through release of fluids, sediments, and melts from dehydration and melting of subducting oceanic slab, respectively (Brandl et al, 2017;Inglis et al, 2017;Masuda & Fryer, 2015). Magmas produced in mid-oceanic ridge settings and island-arc systems reflect distinct geochemical features that link respective magmatic processes and geodynamic conditions.…”

Section: Introductionmentioning

confidence: 99%

Geochemical characteristics of basalts from Andaman subduction zone: Implications on magma genesis at intraoceanic back‐arc spreading centres

et al. 2018

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This study reports new petrological and geochemical data for the ocean floor volcanic rocks dredged from the back‐arc basin of the Andaman Sea and elucidates their geochemical characteristics and petrogenetic aspects to provide insights into the melt generation processes, oceanic crust emplacement, and tectonomagmatic evolution of the Andaman back‐arc basin. The studied samples are porphyritic basalts with olivine, plagioclase, and clinopyroxene representing the phenocrysts and the groundmass composition marked by plagioclase microlites, granular clinopyroxenes, and glass. Geochemical characteristics of these basalts reflect sub‐alkaline, tholeiitic composition of precursor magma that experienced clinopyroxene‐Ti magnetite fractionation. The overall geochemical trend for these basalts reflects LILE–HFSE–REE depleted MORB‐type chemistry which is modified by input from subduction‐derived components. Pronounced enrichment in selected LREE (Nd) and incompatible fluid‐mobile trace elements like Ba with positive primitive mantle‐normalized La and Sr anomalies in the majority of these basalts are attributed to transport and influx of slab‐dehydrated fluids and sediments into the depleted back‐arc mantle asthenosphere from the dehydrating subducted oceanic lithosphere in the volcanic arc front during initial stage of back‐arc rifting in the Andaman Sea. The studied basalts were derived by 10%–30% partial melting of a heterogeneous spinel lherzolitic mantle at a shallow depth. The chemical heterogeneity of the spinel lherozolite source suggests an enrichment‐depletion history of back‐arc mantle correlatable with the transitional tectonic evolution of the back‐arc basin from an initial rifting to matured spreading stage. The depleted MORB‐type mantle (DMM) beneath a juvenile back arc experienced infiltration of fluids and subduction‐derived components (SDC) from proximal subducting oceanic slab that gradually diminished with increasing distance from the arc and progressive back‐arc spreading. The episodes of melt generation and magma genesis invoke a gradual geodynamic transition from incipient back‐arc rifting to matured back‐arc spreading stages in the tectonomagmatic evolution of the Andaman back‐arc basin system. Oceanic crust generated during the incipient rifting stage sampled arc‐type melts enriched and hydrated by subduction inputs and fluid flux, while oceanic crust formed during matured back‐arc extension stage inherited trace element depleted MORB‐type mantle signatures devoid of subduction influence.

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The Role of Redox Processes in Determining the Iron Isotope Compositions of Minerals, Melts, and Fluids

Sossi¹,

Debret²

2021

Magma Redox Geochemistry

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Stable isotope fractionation is a response to the minimisation of free energy associated with differences in vibrational frequencies during substitution of isotopic masses between two phases. Site properties are dictated by the bonding environment of iron, and influence its 'force constant', a descriptor for bond strength. Because iron readily transitions between its ferrous (Fe 2+ ) and ferric (Fe 3+ ) state over the oxygen fugacities (fO 2 ) of terrestrial magmas, redox processes are presumed to control iron isotope fractionation. In fact, both co-ordination and redox state are key to interpreting iron isotope variations in high-temperature, high-pressure geological systems. Determinations of iron force constants by experimental, theoretical and spectroscopic means in minerals, melts and fluids are reviewed, emphasising the effect of composition in influencing isotopic fractionation. Within this framework, the application of numerical models of partial melting to iron isotope variations in oceanic basalts and subduction-zone (or arc) magmas has shed light on their genesis. The influence of melt composition, mineral mode and fluid exsolution in producing iron isotope fractionation in evolving magmas is explored. Iron isotopic signatures in magmatic rocks are linked to that of their sources, and are influenced by the iron isotopic evolution of subducting slabs and transfer of fluids to the mantle wedge. 2.0. Principles and nomenclature Ratios of two isotopes, n and d of an element, E, are generally expressed relative to their ratio in a standard in delta notation, which is given by:(1) 𝛿 𝑛/𝑑 𝐸 = ( ( 𝑛 𝐸/ 𝑑 𝐸) 𝑠𝑎𝑚𝑝𝑙𝑒

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

Cited by 71 publications

References 111 publications

Zinc isotope analyses of singularly small samples (<5 ng Zn): Investigating chondrule-matrix complementarity in Leoville

Zinc isotope analyses of singularly small samples (<5 ng Zn): Investigating chondrule-matrix complementarity in Leoville

Geochemical characteristics of basalts from Andaman subduction zone: Implications on magma genesis at intraoceanic back‐arc spreading centres

The Role of Redox Processes in Determining the Iron Isotope Compositions of Minerals, Melts, and Fluids

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

Cited by 71 publications

References 111 publications

Zinc isotope analyses of singularly small samples (<5 ng Zn): Investigating chondrule-matrix complementarity in Leoville

Zinc isotope analyses of singularly small samples (<5 ng Zn): Investigating chondrule-matrix complementarity in Leoville

Geochemical characteristics of basalts from Andaman subduction zone: Implications on magma genesis at intraoceanic back‐arc spreading centres

The Role of Redox Processes in Determining the Iron Isotope Compositions of Minerals, Melts, and Fluids

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Zinc isotope analyses of singularly small samples (<5 ng Zn): Investigating chondrule-matrix complementarity in Leoville

Zinc isotope analyses of singularly small samples (<5 ng Zn): Investigating chondrule-matrix complementarity in Leoville