Tracing Earth's Volatile Delivery With Tin

Kubik, Edith; Siebert, J.; Mahan, Brandon; Creech, John; Blanchard, Ingrid; Agranier, Arnaud; Shcheka, Svyatoslav; Moynier, Frédéric

doi:10.1029/2021jb022026

Cited by 8 publications

(6 citation statements)

References 129 publications

(276 reference statements)

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“…Previous experiments have shown that even at high T conditions there is a significant fractionation of isotopes of elements such as carbon (Satish‐Kumar et al., 2011), nitrogen (Y. Li, Marty, et al., 2016; Shi et al., 2022), silicon (Shahar et al., 2009), and tin (Kubik et al., 2021) associated with core formation. This fractionation occurs due to the influence of mass differences on Gibbs energies in coexisting metal and silicate phases, and scales with ( m h – m l )/( m h ‧ m l ) (Equation S8 in Supporting Information S1).…”

Section: Resultsmentioning

confidence: 99%

Earth's “Missing” Chlorine May Be in the Core

Yuan,

Steinle‐Neumann

2024

JGR Solid Earth

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The budget of volatile halogens in the bulk silicate Earth, fluorine and chlorine, differs distinctly from that of chondritic meteorites. Arguably, the bulk silicate Earth shows a low abundance of Cl, while the F budget is in line with the expected volatility trend. One hypothesis for the missing Cl is its sequestration into Earth's core during planetary segregation, but experimental data on partitioning between silicate and metallic melts are limited in pressure and remain inconclusive. Here we use computational quantum mechanical methods to study F and Cl geochemistry during core–mantle differentiation over a wide pressure and temperature range. Our calculations reveal that with increasing pressure and temperature, chlorine shows an enhanced affinity for iron metal. The Cl metal–silicate partition coefficient increase from −1.89 ± 0.84 at 10 GPa and 3000 K to 1.62 ± 0.80 at 130 GPa and 5000 K, while corresponding calculations for F show minimal variations in metal–silicate partitioning across the pressure–temperature conditions investigated, yielding values between −3.61 ± 0.81 and −3.37 ± 0.80. The shift in shows a transition from lithophile to siderophile behavior. Further calculations on isotopic partitioning show negligible fractionation of Cl isotopes (37Cl/35Cl) between the mantle and core. Our results suggest that metallic iron within Earth's mantle and core may serve as an important Cl reservoir, potentially accounting for up to 40% of Earth's overall Cl inventory.

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Section: Resultsmentioning

confidence: 99%

Earth's “Missing” Chlorine May Be in the Core

Yuan,

Steinle‐Neumann

2024

JGR Solid Earth

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“…Besides, recently Kubik et al found an enrichment of the heavy Sn isotope in Fe−Sn(−S) metallic liquids rather than silicate melts at high T−P conditions, 34 which was likely to indicate other controlling factors of Sn isotope fractionation (e.g., metallic structures or T−P conditions) and need further investigation. relative to NRIXS measurements has also been found in minerals of other Mossbauer-active elements such as Fe and Eu.…”

Section: Controlling Factors Of Sn Isotope Fractionationmentioning

confidence: 99%

“…30−32 The knowledge of equilibrium Sn isotope fractionation factors among minerals is the quantitative basis for understanding the fractionation mechanisms of Sn isotopes and investigating geological and cosmochemical processes using Sn isotopes. Currently, the lack of such knowledge has limited the interpretations of Sn isotope data in nature and experiments (e.g., ref 14,33,34).…”

Section: Introductionmentioning

confidence: 99%

“…It has been found that the change of the Sn oxidation state can result in large Sn isotope fractionation among Sn-bearing minerals, − but the effect of the coordination environment has only been investigated for aqueous and vaporous Sn species. − The knowledge of equilibrium Sn isotope fractionation factors among minerals is the quantitative basis for understanding the fractionation mechanisms of Sn isotopes and investigating geological and cosmochemical processes using Sn isotopes. Currently, the lack of such knowledge has limited the interpretations of Sn isotope data in nature and experiments (e.g., ref ,, ).…”

Section: Introductionmentioning

confidence: 99%

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Equilibrium Sn Isotope Fractionation among Sn-Bearing Minerals

Wang,

She,

Sun

et al. 2023

ACS Earth Space Chem.

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Quantifying equilibrium Sn isotope fractionation among Sn-bearing minerals is fundamental for understanding the partitioning of Sn isotopes during various geological and cosmochemical processes. In this study, we used first-principles calculations to evaluate equilibrium Sn isotope fractionations among 13 Sn-bearing minerals. The Sn isotope reduced partition function ratios (RPFRs or β factors) calculated with the state-of-the-art r2SCAN functional decrease in the order of brannockite > eakerite > megawite > cassiterite > pirquitasite > kesterite > stannite > berndtite-2T ≈ hydroromarchite > romarchite > ottemannite > herzenbergite > native tin. At high temperatures, the variation range can still be large. The 1000 ln122/116 β values show a linear relationship with the average Sn force constants in minerals. The results indicate that under equilibrium, the preference of heavy Sn isotope partitioning decreases in the order of Sn(IV) minerals > Sn(II) minerals > native tin. Stannic silicates are enriched in heavy Sn isotopes among all of the minerals, and oxides are enriched in heavy Sn isotopes relative to sulfides in addition to the effect of the oxidation state of Sn. The RPFRs for hydrothermal Sn species are between those of oxide and sulfide minerals at the corresponding oxidation states. These results provide a data set of equilibrium Sn isotope fractionation factors, which indicates that the changes in the coordination environment and in the oxidation state can have similar effects on equilibrium Sn isotope fractionation. This could be important in interpreting natural Sn isotope variabilities.

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“…Tin is one of the few trace elements that shows secular increase in abundance in glacial deposits through time (Gaschnig et al, 2016) due to its incompatible behaviour. Significant Sn isotope fractionation has been reported in terrestrial samples (Badullovich et al, 2017;Wang et al, 2018) and in a number of geological processes such as liquid-vapour separation (She et al, 2020), redox processes (Roskosz et al, 2020), metal-silicate equilibrium (Kubik et al, 2021), and hydrothermal processes (Liu et al, 2021), indicating that Sn isotopes may be fractionated during continental crust formation. This raises the question of whether there may also be a secular evolution of the Sn isotopic composition in glacial diamictites.…”

Section: Introductionmentioning

confidence: 99%

A baseline for the Sn isotopic composition of the upper continental crust

Kubik,

Moynier,

She

et al. 2024

Geochem. Persp. Let.

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We report high precision Sn isotopic compositions, expressed as δ 122/118 Sn relative to the NIST3161a standard, for the fine grained matrix of 24 glacial diamictite composites. The diamictites were deposited from the Mesoarchean to the Palaeozoic and sampled from four continents (Africa, Asia, North and South America). They are relatively homogeneous in δ 122/118 Sn, ranging from 0.15 to 0.32 ‰ with an average δ 122/118 Sn value of 0.22 ± 0.14 ‰ (2 s.d., n = 24). The Sn isotopic composition of the diamictites is not influenced by chemical weathering, depositional age, geographic setting, atmospheric oxygen content or magmatic differentiation processes in the source region. As such, the average provides a robust estimate of the Sn isotopic composition of the bulk upper continental crust (UCC). This baseline is within the range of, but isotopically lighter than, the current depleted mantle estimate (0.37 ± 0.09 ‰; 2 s.d., n = 12) and bulk silicate Earth (0.38 ± 0.11 ‰; 2 s.d., n = 9). It also overlaps with the very few available measurements made on andesites, granites, a granodiorite and a rhyolite.

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Tracing Earth's Volatile Delivery With Tin

Cited by 8 publications

References 129 publications

Earth's “Missing” Chlorine May Be in the Core

Earth's “Missing” Chlorine May Be in the Core

Equilibrium Sn Isotope Fractionation among Sn-Bearing Minerals

A baseline for the Sn isotopic composition of the upper continental crust

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