Tungsten isotopic evolution during late-stage accretion: Constraints on Earth–Moon equilibration

Nimmo, F.; O’Brien, D. P.; Kleine, T.

doi:10.1016/j.epsl.2010.02.003

Cited by 60 publications

(86 citation statements)

References 51 publications

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“…A final and pervasive Moon-forming event must eventually have set the ε 182 W value of the pre-late veneer terrestrial mantle (Münker, 2010;Nimmo et al, 2010;Pahlevan and Stevenson, 2007;Touboul et al, 2007) and also led to the formation of a terrestrial magma ocean (Canup, 2004;Walter et al, 2004). It is as yet unclear to what degree the cores of the proto-Earth and the impactor merged during this event (i.e.…”

Section: A Unifying Model For W Isotope and Hse Constraints In Archeamentioning

confidence: 96%

Tungsten isotope composition of the Acasta Gneiss Complex

Willbold

Mojzsis

Chen

et al. 2015

Earth and Planetary Science Letters

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Editor: B. Marty Keywords: Archean mantle crust late veneer tungsten isotopes Acasta Gneiss Complex High-precision tungsten ( 182 W/ 184 W) isotope measurements on well-characterised mafic and felsic samples of the ca. 3960 Ma Acasta Gneiss Complex (AGC; Northwest Territories, Canada) show radiogenic ε 182 W values between +0.06 to +0.15. Two ca. 3600 Ma felsic samples from this terrane have ε 182 W ∼ 0 and are the oldest samples so far documented to have a W isotopic composition indistinguishable from that of the modern mantle. The ε 182 W data are correlated with ε 142 Nd (Roth et al., 2014) and weattribute this variability to incomplete metamorphic homogenisation of the 3960 Ma protolith with more recent material in a 3370 Ma tectono-thermal event. Notably, the value of the positive ε 182 W anomalies seen in the 3960 Ma AGC samples that are least affected by metamorphic homogenisation is comparable to that observed in other early Archean rocks (Isua Supracrustal Belt, Greenland; Nuvvuagittuq Supracrustal Belt, Canada) and the late Archean Kostomuksha komatiites (Karelia). This demonstrates a globally constant signature. We infer that the presence of a pre-late veneer mantle represents the most straightforward interpretation of a uniform distribution of ε 182 W ∼ +0.15 value in Archean rocks of different ages. We show that such a notion is compatible with independent constraints from highly siderophile element abundances in mafic and ultra-mafic Archean mantle-derived rocks. The absence of anomalous ε 182 W and ε 142 Nd so far measured in samples younger than ca. 2800 Ma suggests progressive convective homogenisation of silicate reservoirs. The downward mixing of an upper mantle rich in late-delivered meteoritic material might account for these combined observations.

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Section: A Unifying Model For W Isotope and Hse Constraints In Archeamentioning

confidence: 96%

Tungsten isotope composition of the Acasta Gneiss Complex

Willbold

Mojzsis

Chen

et al. 2015

Earth and Planetary Science Letters

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“…Of all the MSE, the modification of the mantle by giant impact has been most frequently studied using W isotopes, because of the radiogenic tracer capability inherent in the system (Halliday, 2004;Nimmo et al, 2010;Dwyer et al, 2014). Unfortunately, the W isotopic composition of the mantle today can presently provide only limited constraints regarding the nature of the giant impactor.…”

Section: The Final ~10 Wt % Of Accretionmentioning

confidence: 98%

In search of late-stage planetary building blocks

et al. 2015

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“…The parameters used are therefore those relevant to such a collision and are summarized in table 1. The parameters that are the most poorly constrained and strongly influence the calculations (also see [132]) are the degree of equilibration between the impactor core and proto-Earth mantle (k), the metal-silicate partition coefficient for W during lunar core formation (D M ) and the fraction of the Moon that came from the impactor versus the proto-Earth mantle (h). For this reason, we present a range of simulations by varying k, D and h over acceptable ranges (0 < k < 0.4 [134,135]; 50 < D < 100 [128,136]; 0.5 < h < 0.9 [9,137]).…”

Section: Hf-w In the Earth-moon-impactor Systemmentioning

confidence: 99%

“…Finally, k is the fraction of the impactor core reequilibrating with the Earth mantle before being absorbed into Earth's core, i.e. k = 1 indicates full equilibration of the impactor core with the target mantle and k = 0 indicates no re-equilibration [131][132][133].…”

Section: Hf-w In the Earth-moon-impactor Systemmentioning

confidence: 99%

Geochemical arguments for an Earth-like Moon-forming impactor

Dauphas

Burkhardt

Warren

et al. 2014

Phil. Trans. R. Soc. A.

128

103

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Geochemical evidence suggests that the material accreted by the Earth did not change in nature during Earth's accretion, presumably because the inner protoplanetary disc had uniform isotopic composition similar to enstatite chondrites, aubrites and ungrouped achondrite NWA 5363/5400. Enstatite meteorites and the Earth were derived from the same nebular reservoir but diverged in their chemical evolutions, so no chondrite sample in meteorite collections is representative of the Earth's building blocks. The similarity in isotopic composition (Δ 17 O, ε 50 Ti and ε 54 Cr) between lunar and terrestrial rocks is explained by the fact that the Moon-forming impactor came from the same region of the disc as other Earth-forming embryos, and therefore was similar in isotopic composition to the Earth. The heavy δ 30 Si values of the silicate Earth and the Moon relative to known chondrites may be due to fractionation in the solar nebula/protoplanetary disc rather than partitioning of silicon in Earth's core. An inversion method is presented to calculate the Hf/W ratios and ε 182 W values of the proto-Earth and impactor mantles for a given Moon-forming impact scenario. The similarity in tungsten isotopic composition between lunar and terrestrial rocks is a coincidence that can be explained in a canonical giant impact scenario if an early formed embryo (two-stage model age of 10–20 Myr) collided with the proto-Earth formed over a more protracted accretion history (two-stage model age of 30–40 Myr).

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Tungsten isotopic evolution during late-stage accretion: Constraints on Earth–Moon equilibration

Cited by 60 publications

References 51 publications

Tungsten isotope composition of the Acasta Gneiss Complex

Tungsten isotope composition of the Acasta Gneiss Complex

In search of late-stage planetary building blocks

Geochemical arguments for an Earth-like Moon-forming impactor

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