Magnesium stable isotopes support the lunar magma ocean cumulate remelting model for mare basalts

Sedaghatpour, Fatemeh; Jacobsen, S. B.

doi:10.1073/pnas.1811377115

Cited by 29 publications

(27 citation statements)

References 65 publications

(160 reference statements)

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“…This was also reported to bias the oxygen isotope compositions of basalts 75075 and 15555 (Spicuzza et al, 2007;Liu et al, 2010), and, more recently, the silicon isotope composition of ferroan anorthosites 65035 and 60015 (Poitrasson and Zambardi, 2015), when powders were produced from rock chips weighing less than ~100 mg (Armytage et al, 2012). Moreover, for basalt 15555, an anomalously light Mg isotope signature reported recently (Sedaghatpour and Jacobsen, 2019), combined with significant Fe-Mg inter-mineral diffusion affecting Mg isotope systematics in olivine crystals of 15555 (Richter et al, 2016), provide an additional clue for possible sample Fe isotope heterogeneity issue (see Table 1).…”

Section: The Key Role Of the Sample Size For Representative Fe Isotopmentioning

confidence: 71%

“…This partly results from analytical difficulties to determine accurate 26 Mg values of silicate rock samples. Furthermore, lunar samples appear to yield heterogeneous 26 Mg values, with high-Ti basalts tending towards lighter isotopic compositions according to Sedaghatpour et al (2013) and Sedaghatpour and Jacobsen (2019) whereas Wiechert and Halliday (2007) found the opposite. Given these controversies, it is still difficult at this point to use Mg isotope compositions to discuss planet formation and differentiation processes.…”

Section: Evaluation Of the Model With Other Stable Isotope Systemsmentioning

confidence: 96%

“…As a result, Liu et al (2010) concluded that: 1) partial melting in the lunar mantle probably did not produce Fe isotope fractionation, and 2) Fe isotope compositions of low-Ti and high-Ti mare basalts directly mirror those of their corresponding lunar mantle sources. These conclusions have recently been challenged by Sedaghatpour and Jacobsen (2019) on the basis of a fractional crystallization model. However, these models are frequently underconstrained, with many of the unknown parameters adjusted to fit the observed bulk-rock analyses (see review by Dauphas et al, 2017).…”

Section: Iron Isotope Composition Of Different Lunar Reservoirsmentioning

confidence: 99%

“…There is no consensus yet as to whether the majority of terrestrial bodies have a chondritic 26 Mg signature (see recent review by Teng, 2017, and see also Sedaghatpour and Jacobsen, 2019), or if the Earth is isotopically heavier (Wiechert and Halliday, 2007;Hin et al, 2017). This partly results from analytical difficulties to determine accurate 26 Mg values of silicate rock samples.…”

Section: Evaluation Of the Model With Other Stable Isotope Systemsmentioning

confidence: 99%

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A reassessment of the iron isotope composition of the Moon and its implications for the accretion and differentiation of terrestrial planets

Poitrasson

Zambardi

Magna

et al. 2019

Geochimica et Cosmochimica Acta

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Section: The Key Role Of the Sample Size For Representative Fe Isotopmentioning

confidence: 71%

Section: Evaluation Of the Model With Other Stable Isotope Systemsmentioning

confidence: 96%

Section: Iron Isotope Composition Of Different Lunar Reservoirsmentioning

confidence: 99%

Section: Evaluation Of the Model With Other Stable Isotope Systemsmentioning

confidence: 99%

See 2 more Smart Citations

A reassessment of the iron isotope composition of the Moon and its implications for the accretion and differentiation of terrestrial planets

Poitrasson

Zambardi

Magna

et al. 2019

Geochimica et Cosmochimica Acta

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“…Lunar materials from the Apollo missions and as meteorites have been shown to form from the same silicate reservoirs based on stable isotopes of refractory major rock-forming elements (e.g., O, Mg, Si, Fe; Spicuzza et al, 2007: Liu et al, 2010Armytage et al, 2012;Sossi and Moynier, 2017;Sedaghatpour and Jacobsen, 2019). For moderately volatile elements like zinc, the isotopic compositions of lunar crustal samples reflect effects of evaporation, condensation, mixing and contamination at the lunar surface (Moynier et al, 2006;Herzog et al, 2009;Paniello et al, 2012a;Kato et al, 2015;Day et al, 2017a), as well as the Zn-bearing phases present in samples.…”

Section: Evaporation Condensation Mixing and Contamination At The Lmentioning

confidence: 99%

Mare basalt meteorites, magnesian-suite rocks and KREEP reveal loss of zinc during and after lunar formation

Day

Kooten

Hofmann

et al. 2020

Earth and Planetary Science Letters

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Isotopic compositions of reservoirs in the Moon can be constrained from analysis of rocks generated during lunar magmatic differentiation. Mare basalts sample the largest lunar mantle volume, from olivine-and pyroxene-rich cumulates, whereas ferroan anorthosites and magnesian-suite rocks represent early crustal materials. Incompatible element enriched rocks, known as 'KREEP,' probably preserve evidence for the last highly differentiated melts. Here we show that mare basalts, including Apollo samples and meteorites, have remarkably consistent δ 66 Zn values (+1.4 ± 0.2) and Zn abundances (1.5 ± 0.4 ppm). Analyses of magnesian-suite rocks show them to be characterized by even heavier δ 66 Zn values (2.5 to 9.3) and low Zn concentrations. KREEP-rich impact melt breccia Sayh al Uhaymir 169 has a nearly identical Zn composition to mare basalts (δ 66 Zn = 1.3) and a low Zn abundance (0.5 ppm). Much of this variation can be explained through progressive depletion of Zn and preferential loss of the light isotopes in response to evaporative fractionation processes during a lunar magma ocean. Samples with isotopically light Zn can be explained by either direct condensation or mixing and contamination processes at the lunar surface. The δ 66 Zn of Sayh al Uhaymir 169 is probably compromised by mixing processes of KREEP with mafic components. Correlations of Zn with Cl isotopes suggest that the urKREEP reservoir should be isotopically heavy with respect to Zn, like magnesian-suite rocks. Current models to explain how and when Zn and other volatile elements were lost from the Moon include nebular processes, prior to lunar formation, and planetary processes, either during giant impact, or magmatic differentiation. Our results provide unambiguous evidence for the latter process. Notwithstanding, with the currently available volatile stable isotope datasets, it is difficult to discount if the Moon lost its volatiles relative to Earth either during giant impact or exclusively from later magmatic differentiation. If the Moon did begin initially volatile-depleted, then the mare basalt δ 66 Zn value likely preserves the signature, and the Moon lost 96% of its Zn inventory relative to Earth and was also characterized by isotopically heavy Cl (δ 37 Cl = ≥8). Alternative loss mechanisms, including erosive impact removing a steam atmosphere need to be examined in detail, but nebular processes of volatile loss do not appear necessary to explain lunar and terrestrial volatile inventories.

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Isotope Fractionation Processes of Selected Elements

Hoefs¹

2021

Springer Textbooks in Earth Sciences, Geography and Environment

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Magnesium stable isotopes support the lunar magma ocean cumulate remelting model for mare basalts

Cited by 29 publications

References 65 publications

A reassessment of the iron isotope composition of the Moon and its implications for the accretion and differentiation of terrestrial planets

A reassessment of the iron isotope composition of the Moon and its implications for the accretion and differentiation of terrestrial planets

Mare basalt meteorites, magnesian-suite rocks and KREEP reveal loss of zinc during and after lunar formation

Isotope Fractionation Processes of Selected Elements

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