U-Pb age of zircon and the history of impact transformations of the Chelyabinsk meteorite

We studied three lithologies (light and dark chondritic and impact melt rock) differing in shock stage from the LL5 chondrite Chelyabinsk. Using the 40 Ar-39 Ar dating technique, we identified low-and high-temperature reservoirs within all samples, ascribed to K-bearing oligoclase feldspar and shock-induced jadeite-feldspar glass assemblages in melt veins, respectively. Trapped argon components had variable 40 Ar/ 36 Ar ratios even within lowand high-temperature reservoirs of individual samples. Correcting for trapped argon revealed a lithology-specific response of the K-Ar system to shock metamorphism, thereby defining two distinct impact events affecting the Chelyabinsk parent asteroid (1) an intense impact event~1.7 AE 0.1 Ga ago formed the light-dark-structured and impact-veined Chelyabinsk breccia. Such a one-stage breccia formation is consistent with petrological observations and was recorded by the strongly shocked lithologies (dark and impact melt) where a significant fraction of oligoclase feldspar was transformed into jadeite and feldspathic glass; and (2) a young reset event~30 Ma ago particularly affected the light lithology due to its low argon retentivity, while the more retentive shock-induced phases were more resistant against thermal reset. Trapped argon with 40 Ar/ 36 Ar ratios up to 1900 was likely incorporated during impact-induced events on the parent body, and mixed with terrestrial atmospheric argon contamination. Had it not been identified via isochrons based on high-resolution argon extraction, several geochronologically meaningless ages would have been deduced.

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“…; Skublov et al. ). However, this interpretation may be incorrect owing to an incomplete degree of isotopic reset.…”

Section: Discussionmentioning

confidence: 97%

“…; Skublov et al. ), creating the impression of a strongly heterogeneous material that experienced a large variety of impact events (Lindsay et al. ; Righter et al.…”

Section: Introductionmentioning

confidence: 99%

The Chelyabinsk meteorite: Thermal history and variable shock effects recorded by the ⁴⁰Ar‐³⁹Ar system

Trieloff

Korochantseva

Buikin

et al. 2017

Meteorit & Planetary Scien

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“…Color regions are from Belousova et al (). This diagram includes data from H adean detrital zircons (Crowley, Myers, Sylvester, & Cox, ; Hoskin & Black, ; Maas, Kinny, Williams, Froude, & Compston, ; Peck, Valley, Wilde, & Graham, ; Wilde, Valley, Peck, & Graham, ), zircons separated from terrestrial igneous rocks (Ballard et al, ; Belousova et al, ; Breiter et al, ; Griffin et al, ; Pankhurst et al, ; Suzuki et al, ; Wang et al, ), zircons in meteorite (Skublov et al, ). See Table S1 for the data of OD3 and MES…”

Section: Discussionmentioning

confidence: 99%

“…HED meteorite, and ordinary chondrite; Bonin, 2012;Bonin, Bébien, & Masson, 2002;Terada & Bischoff, 2009;Warren, Taylor, Keil, Shirley, & Wasson, 1983) and their geochemical similarities to Atype granites raise the possibility that A-type granitic rocks existed in the Hadean Earth or on other planets (Bonin, 2007 (Ballard et al, 2002;Belousova et al, 2006;Breiter et al, 2014;Griffin et al, 2002;Pankhurst et al, 2013;Suzuki et al, 2014;Wang et al, 2012), zircons in meteorite (Skublov et al, 2015). See Table S1 for the data of OD3 and MES Among the four types of granites, the A-type granites are suggested to have a tectonically different origin than the other three granite types; I-, S-, and M-type granites are basically related to volcanism at a subduction zone, whereas A-type granites are anorogenic in origin.…”

Section: Discussionmentioning

confidence: 99%

“…Therefore, this kind of information could be useful for granite petrogenetic studies. Skublov et al (2015) report trace elements data in two zircons from the LL5 ordinary chondrite Chelyabinsk. Both zircon grains are characterized by high Nb contents and high Nb/Sr ratios, and one grain exhibits a strong negative Eu anomaly (white squares in Figure 9a).…”

Section: Discussionmentioning

confidence: 99%

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Geochemical characteristics of zircons in the Ashizuri A‐type granitoids: An additional granite topology tool for detrital zircon studies

et al. 2017

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Zircon is resistant to alteration over a wide range of geological environments, and isotopic ratios within the mineral provide constraints on ages and their parental magmas. Trace element compositions in zircon are also expected to reflect those of their parent magmas, and have a potential as essential indicators for their host rocks. Because most detrital zircons that accumulate at river mouths are derived primarily from granitoids, the classification of zircon within granitoids is potentially meaningful. This study employs the conventional classification scheme of granites (I-, S-, M-, and A-types). To clarify geochemical characteristics of zircons in A-type granites, trace element compositions of zircons extracted from the A-type Ashizuri granitoids were examined. Zircons from the Ashizuri granitoids commonly show enrichments of heavy rare earth elements and positive Ce anomalies, indicating that these zircons were igneous in origin. In addition, zircons in these A-type granites are characterized by enrichments of Nb, Y, Ta, Th, and U and strong negative Eu anomalies, which exhibit good positive correlations with those in their whole rocks. This fact indicates that these signatures in zircons reflect well those in their parental bodies and are useful in identifying zircons derived from A-type granite. Based on compilations of available data, zircons from A-type granites can be clearly discriminated from other-types of granites within Nb/Sr-Eu anomaly, U/Sr-Eu anomaly, Nb/Sr-U/Sr, and Nb/Sr-Ta/Sr cross-plots. All indices used in these diagrams were selected based on the geochemical features of both zircon and whole rock of A-type granites. Application of these discrimination diagrams to detrital zircons will likely provide further insights. For example, some Hadean detrital zircons plot in similar fields to A-type granites, implying the existence of A-type magmatism in the Earth's earliest history. K E Y W O R D SAshizuri, A-type granite, HFSE, REE, zircon | INTRODUCTIONZircons are often used as geochronological and geochemical indicators for constraining the nature of their host rocks. Recent developments of analytical methods enable us to extract information concerning the host rock from a single zircon grain. As one such example, contribution rates of mature sediments into granitoid magma through geologic time have been examined based on compilations of oxygen isotope ratios of zircons extracted from granites (Valley et al., 2005) and of detrital zircons in river mouth sands (Iizuka et al., 2013). Belousova, Griffin, O'Reilly, and Fisher (2002) examined trace element contents in zircons from a variety of rock types and proposed some discrimination diagrams, but found that most rocks are inseparable except for peculiar rocks (kimberlite, carbonatite, and nepheline-syenite). Basically, most detrital zircons that accumulate at river mouths are derived primarily from granitoids (Hawkesworth, Cawood, Kemp, Storey, & Dhuime, 2009), and their U-Pb age populations reflect the age variation of the hinterlan...

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Ar‐Ar and U‐Pb ages of Chelyabinsk and a re‐evaluation of its impact chronology

Beard

Swindle

Lapen

et al. 2022

Meteorit & Planetary Scien

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The LL5 chondrite Chelyabinsk has had numerous isotopic studies since its fall in 2013. These data have been used to suggest ~8 impact events recorded from multiple isotopic systems (e.g., Ar‐Ar, U–Pb, Sm‐Nd, Rb‐Sr, among others). We report details of Ar‐Ar and U‐Pb results and re‐evaluate the geochronology of Chelyabinsk. Argon has the youngest Ar‐Ar age recorded in meteorites, 25 ± 11 Ma, and an older resetting event at ~2550 Ma. The U‐Pb analysis has an upper concordia age of 4456 ± 23 Ma and a lower concordia age of 184 ± 200 Ma. The lower concordia intercept represents a later thermal event (e.g., an impact), the most recent time that lead loss occurred, and could represent resetting by the youngest event recorded by Ar‐Ar. Combining our data with literature results, we find strong evidence of at least four impact events (~4450, 2550, 1700, 25 Ma), with some evidence for two additional impacts (~3700, 1000 Ma).

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U-Pb age of zircon and the history of impact transformations of the Chelyabinsk meteorite

Cited by 4 publications

References 9 publications

The Chelyabinsk meteorite: Thermal history and variable shock effects recorded by the ⁴⁰Ar‐³⁹Ar system

The Chelyabinsk meteorite: Thermal history and variable shock effects recorded by the ⁴⁰Ar‐³⁹Ar system

Geochemical characteristics of zircons in the Ashizuri A‐type granitoids: An additional granite topology tool for detrital zircon studies

Ar‐Ar and U‐Pb ages of Chelyabinsk and a re‐evaluation of its impact chronology

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U-Pb age of zircon and the history of impact transformations of the Chelyabinsk meteorite

Cited by 4 publications

References 9 publications

The Chelyabinsk meteorite: Thermal history and variable shock effects recorded by the 40Ar‐39Ar system

The Chelyabinsk meteorite: Thermal history and variable shock effects recorded by the 40Ar‐39Ar system

Geochemical characteristics of zircons in the Ashizuri A‐type granitoids: An additional granite topology tool for detrital zircon studies

Ar‐Ar and U‐Pb ages of Chelyabinsk and a re‐evaluation of its impact chronology

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The Chelyabinsk meteorite: Thermal history and variable shock effects recorded by the ⁴⁰Ar‐³⁹Ar system

The Chelyabinsk meteorite: Thermal history and variable shock effects recorded by the ⁴⁰Ar‐³⁹Ar system