Identification of the giant impactor Theia in lunar rocks

Herwartz, Daniel; Pack, Andreas; Friedrichs, Bjarne; Bischoff, A.

doi:10.1126/science.1251117

Cited by 173 publications

(134 citation statements)

References 38 publications

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“…The first possibility is unlikely because enstatite chondrites, which are the best analogs for the parent materials to aubrites, have much more heterogeneous ∆ 17 O values [from -0.32 to +0.16 ‰ for twelve EH3-6 chondrites, and from -0.11 to +0.07 ‰ for sixteen EL3-6 chondrites taken into account only falls and HCl treated finds (Newton et al, 2000)]. Moreover, the level of ∆ 17 O homogeneity shown by the aubrite falls (± 0.010 ‰ (2σ)) is equivalent to that of other bodies which show evidence for an early global stage of melting i.e., 4-Vesta [± 0.014 ‰ (2σ), Greenwood et al, 2005Greenwood et al, , 2014Scott et al, 2009], the angrite-parent body [± 0.014 ‰ (2σ), Greenwood et al, 2005], the main-group pallasites parent body [± 0.016 ‰ (2σ), Greenwood et al, 2006Greenwood et al, , 2015, the Moon [< ± 0.021 ‰ (2σ), Spicuzza et al, 2007;Hallis et al, 2010;Herwartz et al, 2014;Young et al, 2016] and Mars [± 0.026 ‰ (2σ), Franchi et al, 1999]. Thus, the narrow range of oxygen isotope compositions displayed by the aubrites indicates that some form of isotopic homogenization took place on their parent body.…”

Section: Evidence For Early Large-scale Melting On the Aubrite Parenmentioning

confidence: 79%

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The origin of aubrites: Evidence from lithophile trace element abundances and oxygen isotope compositions

Barrat

Greenwood

Keil

et al. 2016

Geochimica et Cosmochimica Acta

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Please cite this article as: Barrat, J.A., Greenwood, R.C., Keil, K., Rouget, M.L., Boesenberg, J.S., Zanda, B., Franchi, I.A., The origin of aubrites: Evidence from lithophile trace element abundances and oxygen isotope compositions, Geochimica et Cosmochimica Acta (2016), doi: http://dx.doi.org/10. 1016/j.gca.2016.07.025 This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. Leaching experiments were undertaken to investigate the contribution of sulfides to the whole rock 3

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Section: Evidence For Early Large-scale Melting On the Aubrite Parenmentioning

confidence: 79%

“…O plot for aubrites (Clayton and Mayeda, 1996;Newton et al, 2000;Miura et al, 2006;Keil et al, 2011, and this work). Chondritic fields are drawn with data obtained by Clayton et al (1991), Newton et al (2000), and Herwartz et al (2014). (2010).…”

mentioning

confidence: 99%

The origin of aubrites: Evidence from lithophile trace element abundances and oxygen isotope compositions

Barrat

Greenwood

Keil

et al. 2016

Geochimica et Cosmochimica Acta

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“…If this is the case, then our data would seem to support their model; our estimate for BSE is almost identical to the Cu isotope composition of CI chondrites. However, more recent isotope data seems to rule out a CI-like impactor; in particular, precise lunar O isotope data suggests that the impactor had an enstatite chondrite isotope signature (Herwartz et al, 2014). In this instance, again, the enstatite chondrite model would seem most representative of bulk Earth.…”

Section: A) the Earth's Cu Budget Was Established Early In Earth's Acmentioning

confidence: 92%

Copper isotope evidence for large-scale sulphide fractionation during Earth’s differentiation

Savage¹,

Moynier²,

Chen³

et al. 2015

Geochem. Persp. Let.

160

169

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“…In contrast, meteorites from Mars and Vesta are distinctly different from the Earth, with ∆ 17 O val-ues of 0.32 and -0.28 , respectively (Franchi et al 1999;Clayton & Mayeda 1996). More recent work hints at a slight difference between the Moon and the Earth of ∆ 17 O 0.012 , but the fact remains that the Moon is much more isotopically similar to Earth than samples from any other large object in the solar system (Herwartz et al 2014).…”

Section: Theia and The Moon-forming Impactmentioning

confidence: 96%

The feeding zones of terrestrial planets and insights into Moon formation

Kaib

Cowan

2015

Icarus

105

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The final stage of terrestrial planet formation consists of several hundred approximately lunar mass bodies accreting into a few terrestrial planets. This final stage is stochastic, making it hard to predict which parts of the original planetesimal disk contributed to each of our terrestrial planets. Here we present an extensive suite of terrestrial planet formation simulations that allows quantitative analysis of this process. Although there is a general correlation between a planet's location and the initial semi-major axes of its constituent planetesimals, we concur with previous studies that Venus, Earth, and Mars analogs have overlapping, stochastic feeding zones. We quantify the feeding zone width, ∆a, as the mass-weighted standard deviation of the initial semi-major axes of the planetary embryos and planetesimals that make up the final planet. The size of a planet's feeding zone in our simulations does not correlate with its final mass or semi-major axis, suggesting there is no systematic trend between a planet's mass and its volatile inventory. Instead, we find that the feeding zone of any planet more massive than 0.1M ⊕ is roughly proportional to the radial extent of the initial disk from which it formed: ∆a ≈ 0.25(a max − a min ), where a min and a max are the inner and outer edge of the initial planetesimal disk. These wide stochastic feeding zones have significant consequences for the origin of the Moon, since the canonical scenario predicts the Moon should be primarily composed of material from Earth's last major impactor (Theia), yet its isotopic composition is indistinguishable from Earth. In particular, we find that the feeding zones of Theia analogs are significantly more stochastic than the planetary analogs. Depending on our assumed initial distribution of oxygen isotopes within the planetesimal disk, we find a ∼5% or less probability that the Earth and Theia will form with an isotopic difference equal to or smaller than the Earth and Moon's. In fact we predict that every planetary mass body should be expected to have a unique isotopic signature. In addition, we find paucities of massive Theia analogs and high velocity moon-forming collisions, two recently proposed explanations for the Moon's isotopic composition. Our work suggests that there is still no scenario for the Moon's origin that explains its isotopic composition with a high probability event.

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Identification of the giant impactor Theia in lunar rocks

Cited by 173 publications

References 38 publications

The origin of aubrites: Evidence from lithophile trace element abundances and oxygen isotope compositions

The origin of aubrites: Evidence from lithophile trace element abundances and oxygen isotope compositions

Copper isotope evidence for large-scale sulphide fractionation during Earth’s differentiation

The feeding zones of terrestrial planets and insights into Moon formation

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