Halogens in chondritic meteorites and terrestrial accretion

Clay, P. L.; Burgess, R.; Busemann, H.; Ruzie-Hamilton, Lorraine; Joachim, Bastian; Day, James M.D.; Ballentine, C. J.

doi:10.1038/nature24625

Cited by 67 publications

(91 citation statements)

References 91 publications

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“…Errors are reported as 1 standard deviations, unless otherwise noted. For a CI chondritic composition, we adopted the value proposed by for most elements, with some modifications for halogens (Clay et al, 2017), Mo, Tl, Bi (Wang et al, 2015), highly siderophile elements (Day et al, 2016), and U (Wipperfurth et al, 2018) (Table 2).…”

Section: Datamentioning

confidence: 99%

The composition of Mars

Yoshizaki

McDonough

2020

Geochimica et Cosmochimica Acta

132

154

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Comparing compositional models of the terrestrial planets provides insights into physicochemical processes that produced planet-scale similarities and differences. The widely accepted compositional model for Mars assumes Mn and more refractory elements are in CI chondrite proportions in the planet, including Fe, Mg, and Si, which along with O make up >90% the mass of Mars. However, recent improvements in our understandings on the composition of the solar photosphere and meteorites challenge the use of CI chondrite as an analog of Mars. Here we present an alternative model composition for Mars that avoids such an assumption and is based on data from Martian meteorites and spacecraft observations. Our modeling method was previously applied to predict the Earth's composition. The model establishes the absolute abundances of refractory lithophile elements in the bulk silicate Mars (BSM) at 2.26 times higher than that in CI carbonaceous chondrites. Relative to this chondritic composition, Mars has a systematic depletion in moderately volatile lithophile elements as a function of their condensation temperature. Given this finding, we constrain the abundances of siderophile and chalcophile elements in the bulk Mars and its core. The Martian volatility trend is consistent with ≤7 wt% S in its core, which is significantly lower than that assumed in most core models (i.e., >10 wt% S). Occurrence of ringwoodite at the Martian core-mantle boundary might have contributed to the partitioning of O and H into the Martian core.

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Section: Datamentioning

confidence: 99%

The composition of Mars

Yoshizaki

McDonough

2020

Geochimica et Cosmochimica Acta

132

154

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“…Thus, new estimate of the average iodine concentration in carbonaceous chondrites, 127 I CH = 4.5 × 10 −10 mol g −1 [Clay et al, 2017], gives 129 Xe(I)/ 136 Xe(Pu) CH = 1.5 × 10 3 , which is quite a large value still.…”

Section: Nucleogenic Xenon Isotopes In the Mantlementioning

confidence: 90%

“…Regarding the abundance and source of terrestrial iodine, it should be noted that to provide the planet with volatile components, it is necessary to add ≈ 0.015× M EARTH of a chondrites-like material [Clay et al, 2017;Kramers, 2003;Marty, 2012]. Such an amount corresponds to 127 I BSE ≈ 10 × 10 −9 g g −1 , which is close to the maximum value used by Caracausi et al [2016].…”

Section: Nucleogenic Xenon Isotopes In the Mantlementioning

confidence: 93%

The late Earth's accretion: Processes and materials

Tolstikhin¹

2018

Russ. J. Earth Sci.

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In accord with the standard Earth accretion scenario, the late accretion supervened the last collision with a massive proto-planet, segregation of the core, and (partial) solidification of the magma ocean. These processes took place ≈ 40 Ma after Sun formation or somewhat later. Traces of the processes and respective materials have been preserved as specific elemental and isotopic abundances in the earth's mantle. Pu-238 U-129 I-Xe systematics trace the accreting materials and the rate of mantle mixing and degassing. Recently proposed interpretations of this last systematics appear to be precarious and are particularly discussed in this contribution. During the late accretion a terrestrial regolith, including chondritic and solar-wind-irradiated materials, was rapidly accumulating on the surface of the early thick basaltic crust, enriched in incompatible elements. This early crust had not been preserved. Its overturn(s) into the mantle during several 100th Ma after Sun formation and (partial) isolation from the mantle convection allow all principal observations, related to the informative systematics mentioned above, to be satisfied, providing the transfer of the crust®olith "cake" was not accompanying by fractionation and degassing, in contrast to present-day slab subduction.

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“…The necessary chondritic component is increased further if lower chlorine contents are used (i.e., Clay et al. ). Additionally, an independent estimate that satisfies other isotopic constraints (i.e., Dauphas et al.…”

Section: Differentiated Bodies—earth Mars and Moonmentioning

confidence: 99%

“…To account for 85% of Earth's chlorine by ECs requires 3.6% EC addition when using the highest range of chlorine concentrations . The necessary chondritic component is increased further if lower chlorine contents are used (i.e., Clay et al 2017). Additionally, an independent estimate that satisfies other isotopic constraints (i.e., Dauphas et al 2014) using some amount of ordinary chondrites would require an even larger chondritic component.…”

Section: Chondritic Overprintingmentioning

confidence: 99%

The chlorine isotope composition of iron meteorites: Evidence for the Cl isotope composition of the solar nebula and implications for extensive devolatilization during planet formation

Gargano

Sharp

2019

Meteorit & Planetary Scien

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The bulk chlorine concentrations and isotopic compositions of a suite of non‐carbonaceous (NC) and carbonaceous (CC) iron meteorites were measured using gas source mass spectrometry. The δ37Cl values of magmatic irons range from −7.2 to 18.0‰ versus standard mean ocean chloride and are unrelated to their chlorine concentrations, which range from 0.3 to 161 ppm. Nonmagmatic IAB irons are comparatively Cl‐rich containing >161 ppm with δ37Cl values ranging from −6.1 to −3.2‰. The anomalously high and low δ37Cl values are inconsistent with a terrestrial source, and as Cl contents in magmatic irons are largely consistent with derivation from a chondrite‐like silicate complement, we suggest that Cl is indigenous to iron meteorites. Two NC irons, Cape York and Gibeon, have high cooling rates with anomalously high δ37Cl values of 13.4 and 18.0‰. We interpret these high isotopic compositions to result from Cl degassing during the disruption of their parent bodies, consistent with their low volatile contents (Ga, Ge, Ag). As no relevant mechanisms in iron meteorite parent bodies are expected to decrease δ37Cl values, whereas volatilization is known to increase δ37Cl values by the preferential loss of light isotopes, we interpret the low isotope values of <−5‰ and down to −7.2‰ to most closely represent the primordial isotopic composition of Cl in the solar nebula. Similar conclusions have been derived from low δ37Cl values down to −6, and −3.8‰ measured in Martian and Vestan meteorites, respectively. These low δ37Cl values are in contrast to those of chondrites which average around 0‰ previously explained by the incorporation of isotopically heavy HCl clathrate into chondrite parent bodies. The poor retention of low δ37Cl values in many differentiated planetary materials suggest that extensive devolatilization occurred during planet formation, which can explain Earth's high δ37Cl value by the loss of approximately 60% of the initial Cl content.

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Halogens in chondritic meteorites and terrestrial accretion

Cited by 67 publications

References 91 publications

The composition of Mars

The composition of Mars

The late Earth's accretion: Processes and materials

The chlorine isotope composition of iron meteorites: Evidence for the Cl isotope composition of the solar nebula and implications for extensive devolatilization during planet formation

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