Petrogenesis of main group pallasite meteorites based on relationships among texture, mineralogy, and geochemistry

McKibbin, Seann; Pittarello, Lidia; Makarona, Christina; Hamann, Christopher; Hecht, Lutz; Chernonozhkin, Stepan M.; Goderis, Steven; Claeys, Philippe

doi:10.1111/maps.13392

Cited by 18 publications

(36 citation statements)

References 105 publications

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“…However, the cooling rates determined for pallasite metal and olivine are distinct, suggesting a complex formational history. Earlier suggestions of faster cooling of silicate at high temperature and slower cooling at lower temperatures following the metal-olivine mixing event (Tomiyama and Huss 2005;Yang et al 2010) are supported by Mn-Cr isotope ratio data (McKibbin et al, 2016), although detailed interpretations of pallasite formation histories remain controversial (McKibbin et al, 2019). The exact relationship between PMG and IIIAB iron meteorites (Yang et al, 2010) and how pallasite silicates formed (McKibbin et al, 2013) remain outstanding 4 questions.…”

Section: Introductionmentioning

confidence: 98%

“…The PMG exhibit a limited range of trace element compositions (Wasson and Choi, 2003) and oxygen isotope ratios that are closely related and only different from one another as the result of mass-dependent fractionation processes (Greenwood et al, 2006;Greenwood et al, 2015). The PMG may be further sub-divided into i) a common subgroup, which may represent mechanical mixtures of olivine, chromite, primitive solid metal and evolved metal, and ii) low-MnO and high-FeO subgroups, originating from the core-mantle interface of their planetesimal, where interactions between metal, silicate and other components took place (McKibbin et al, 2019). The trace element systematics of PMG metal (Wasson and Choi, 2003) and preliminary chromite oxygen isotope ratio results (Franchi et al, 2013) indicate a possible link with the IIIAB iron meteorite parent body.…”

Section: Introductionmentioning

confidence: 99%

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New constraints on the formation of main group pallasites derived from in situ trace element analysis and 2D mapping of olivine and phosphate

et al. 2021

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Section: Introductionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

New constraints on the formation of main group pallasites derived from in situ trace element analysis and 2D mapping of olivine and phosphate

et al. 2021

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“…The pallasites have an enigmatic formation history. They have commonly been interpreted to represent the core–mantle boundary, but this has been questioned given their paleomagnetic record of the dynamo, which suggests that they must have formed at a much lower temperature than the molten core (Bryson et al., 2015; Mckibbin et al., 2019; Nichols et al., 2016; Tarduno et al., 2012). In addition, their varied cooling rates have been used to argue that they formed at a variety of depths in a disorganized asteroid reassembled after impact (Yang et al., 2010).…”

Section: Introductionmentioning

confidence: 99%

A Time‐Resolved Paleomagnetic Record of Main Group Pallasites: Evidence for a Large‐Cored, Thin‐Mantled Parent Body

et al. 2021

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The Main Group (MG) pallasites are all thought to originate from the same planetesimal (Greenwood et al., 2006). Temporal variations in core dynamo activity on this parent asteroid have been shown by several paleomagnetic studies. For instance, Tarduno et al. (2012) found the first evidence for dynamo activity recorded by magnetic inclusions in olivine crystals from the Imilac and Esquel pallasites. This observation was supported by a paleomagnetic study of the cloudy zone in the Imilac and Esquel pallasites (Bryson et al., 2015). Both studies retrieved paleointensities of ∼100 μT, interpreted as evidence for an active dynamo ∼140-240 Myr after parent body accretion. An active thermal dynamo is predicted to have only lasted for a maximum of ∼40 Myr after accretion (Bryson, Neufeld, et al., 2019;Dodds et al., 2021;Elkins-Tanton et al., 2011). Therefore, this measured magnetic remanence has instead been attributed to compositional convection resulting from core solidification. A subsequent paleomagnetic study of the cloudy zone in the Marjalahti and Brenham pallasites found no evidence of an active dynamo ∼100-120 Myr after accretion (Nichols et al., 2016). Dynamo initiation and the onset of core solidification was therefore predicted to occur between the time at which Brenham and Marjalahti, and subsequently Imilac and Esquel, acquired their paleomagnetic records.

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“…While pallasites are recognised to be mixtures of mantle and core materials, their formation is still debated (Boesenberg et al, 2012;McKibbin et al, 2019;and references therein). Since the 1960s, they are usually seen as samples of the core-mantle transition zone of a differentiated body (e.g., Anders, 1964;Wasson and Choi, 2003), but this hypothesis has been repeatedly challenged.…”

Section: Introductionmentioning

confidence: 99%

Olivines in main-group pallasites: magma-ocean cumulates or partial melting residues?

Barrat¹,

Ferrière²

2021

Geochem. Persp. Let.

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Main-group pallasites (MGPs) are meteorites mainly composed of Fe-Ni metal and olivines, the latter being considered as one of the largest sampling of extraterrestrial mantle material available for study on Earth. We analysed the rare earth element (REE) concentrations of olivines from six MGPs to understand better the processes of formation of their parent mantle. All the investigated samples display very low REE abundances, and enrichments in both light REEs and heavy REEs. We interpret the light REE enrichments as a fingerprint of terrestrial contamination. The least contaminated olivines have higher heavy REE enrichments than those inferred for olivines directly crystallised in a magma ocean. Such enrichments in heavy REEs are possible if the mantle of the MGPs parent body is a residue of partial melting from a chondritic source. Alternatively, re-melting of magma ocean cumulates would explain both the homogeneity of the Δ 17 O values of MGPs, and the heavy REE enrichments of the olivines.

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Petrogenesis of main group pallasite meteorites based on relationships among texture, mineralogy, and geochemistry

Cited by 18 publications

References 105 publications

New constraints on the formation of main group pallasites derived from in situ trace element analysis and 2D mapping of olivine and phosphate

New constraints on the formation of main group pallasites derived from in situ trace element analysis and 2D mapping of olivine and phosphate

A Time‐Resolved Paleomagnetic Record of Main Group Pallasites: Evidence for a Large‐Cored, Thin‐Mantled Parent Body

Olivines in main-group pallasites: magma-ocean cumulates or partial melting residues?

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