TY - JOUR
T1 - The most primitive CM chondrites, Asuka 12085, 12169, and 12236, of subtypes 3.0–2.8
T2 - Their characteristic features and classification
AU - Kimura, M.
AU - Imae, N.
AU - Komatsu, M.
AU - Barrat, J. A.
AU - Greenwood, R. C.
AU - Yamaguchi, A.
AU - Noguchi, T.
N1 - Funding Information:
The sections were loaned from the National Institute of Polar Research . One of Murchison sections was loaned from T. Fagan. We appreciate the thoughtful reviews by two anonymous reviewers. We also thank the associate editor Kevin Righter for efficient handling of the manuscript. This work was supported by a Grant-in-aids of Ministry of Education, Science, Sport, and Culture of Japanese government , No. 18K03729 to M. K. This study was also supported by National Institute of Polar Research (NIPR) through Project research KP307 and General Collaboration Project no. 30–21. Oxygen isotope studies at the Open University are funded by a consolidated grant from the Science and Technology Facilities Council (STFC) , UK GRANT NUMBER: ST/P000657/1 .
Funding Information:
The three Asuka CMs analyzed in this study have the following oxygen isotope compositions: A 12169: δ17O −4.07‰; δ18O 1.32‰; Δ17O −4.75‰; A 12085: δ17O −4.83‰; δ18O −0.31‰; Δ17O −4.67‰; A 12236: δ17O −4.33‰; δ18O 0.80‰; Δ17O −4.75‰. These analyses are shown in Fig. 10 in relation to analyses of CM2, CO3 and anomalous C2 chondrites taken from the literature (full references to data sources are given in the caption to Fig. 10). The three Auska CMs plot away from the field of “normal” CM2 chondrites (Clayton and Mayeda, 1999; Haack et al., 2012; Hewins et al., 2014) and close to the field of CO3 falls (Alexander et al., 2018). The gap between the COs and CMs, where the Asuka CMs plot, is occupied by a range of C2 and anomalous CM chondrites (Greenwood et al., 2019; Lee et al., 2019). A number of these isotopically anomalous CM-like meteorites, such as LEW 85311 (Lee et al., 2019) and NWA 5958 show many mineralogical and petrological features typical of CMs, but like the Asuka CMs described here, have experienced only limited degrees of aqueous alteration. It therefore seems likely that the CM group extends from almost pristine examples that plot close to the CO3 field in Fig. 10, to highly aqueous altered examples that have isotopically heavy oxygen isotope compositions (top right corner of Fig. 10). EET 96029 (Lee et al., 2016) provides additional evidence in support of this relationship, containing areas which are both minimally altered (EET 96029 AK) and other areas which are heavily altered (EET 96029 OU). A linear regression line through the anomalous C2 samples in Fig. 10 (y = −4.17 + 0.67× R2 = 0.95) passes through the “normal” CM2 field. These relationships are consistent with the CM parent body having experienced highly variable levels of aqueous alteration. In addition, the fact that mildly altered samples, such as the Asuka CMs and NWA 5958, plot close to the CO3 field, and in the case of LEW 85311 actually plots within it, supports the original suggestion of Clayton and Mayeda (1999) that the anhydrous CM precursor material was CO-like, at least in terms of its oxygen isotope composition.The sections were loaned from the National Institute of Polar Research. One of Murchison sections was loaned from T. Fagan. We appreciate the thoughtful reviews by two anonymous reviewers. We also thank the associate editor Kevin Righter for efficient handling of the manuscript. This work was supported by a Grant-in-aids of Ministry of Education, Science, Sport, and Culture of Japanese government, No. 18K03729 to M. K. This study was also supported by National Institute of Polar Research (NIPR) through Project research KP307 and General Collaboration Project no. 30–21. Oxygen isotope studies at the Open University are funded by a consolidated grant from the Science and Technology Facilities Council (STFC), UK GRANT NUMBER: ST/P000657/1.
Publisher Copyright:
© 2020 Elsevier B.V. and NIPR
PY - 2020/12
Y1 - 2020/12
N2 - CM chondrites (CMs) are the most abundant group of carbonaceous chondrites. CMs experienced varying degrees of secondary aqueous alteration and heating that modified or destroyed their primitive features. We have studied three chondrites, Asuka (A) 12085, A 12169, and A 12236. Their modal compositions, chondrule size distributions, and bulk composition indicate that they are CMs. However, the common occurrence of melilite in CAIs and glass in chondrules, abundant Fe–Ni metal, the absence of tochilinite-cronstedtite intergrowths, and almost no phyllosilicates, all suggest that these chondrites, especially A 12169, experienced only minimal aqueous alteration. The textures and compositions of metal and sulfides, the lack of ferroan rims on AOA olivines, the compositional distribution of ferroan olivine, and the Raman spectra of their matrices, indicate that these chondrites experienced neither significant heating nor dehydration. These chondrites, especially A 12169, are the most primitive CMs so far reported. The degree of the alteration increases from A 12169, through A 12236, to A 12085. We propose the criteria for subtypes of 3.0–2.8 for CMs. A 12169, A 12236, and A 12085 are classified as subtype 3.0, 2.9, and 2.8, respectively. The oxygen isotopic composition of the Asuka CMs is consistent with these samples having experienced only a limited degree of aqueous alteration. The CM and CO groups are probably not derived from a single heterogeneous parent body. These chondrites are also of particular significance in view of the imminent return of sample material from the asteroids Ryugu and Bennu.
AB - CM chondrites (CMs) are the most abundant group of carbonaceous chondrites. CMs experienced varying degrees of secondary aqueous alteration and heating that modified or destroyed their primitive features. We have studied three chondrites, Asuka (A) 12085, A 12169, and A 12236. Their modal compositions, chondrule size distributions, and bulk composition indicate that they are CMs. However, the common occurrence of melilite in CAIs and glass in chondrules, abundant Fe–Ni metal, the absence of tochilinite-cronstedtite intergrowths, and almost no phyllosilicates, all suggest that these chondrites, especially A 12169, experienced only minimal aqueous alteration. The textures and compositions of metal and sulfides, the lack of ferroan rims on AOA olivines, the compositional distribution of ferroan olivine, and the Raman spectra of their matrices, indicate that these chondrites experienced neither significant heating nor dehydration. These chondrites, especially A 12169, are the most primitive CMs so far reported. The degree of the alteration increases from A 12169, through A 12236, to A 12085. We propose the criteria for subtypes of 3.0–2.8 for CMs. A 12169, A 12236, and A 12085 are classified as subtype 3.0, 2.9, and 2.8, respectively. The oxygen isotopic composition of the Asuka CMs is consistent with these samples having experienced only a limited degree of aqueous alteration. The CM and CO groups are probably not derived from a single heterogeneous parent body. These chondrites are also of particular significance in view of the imminent return of sample material from the asteroids Ryugu and Bennu.
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U2 - 10.1016/j.polar.2020.100565
DO - 10.1016/j.polar.2020.100565
M3 - Article
AN - SCOPUS:85089738385
SN - 1873-9652
VL - 26
JO - Polar Science
JF - Polar Science
M1 - 100565
ER -