Grove Mountains CM-Type Chondrites: History
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CM chondrite is the most important carbonaceous chondrite containing abundant Ca, Al-rich inclusions (CAIs) and other interesting objects, which probably experienced early condensation processes in the Solar Nebula environment and later alteration in parent body surroundings. Thus, it is a vital raw material to explore in the formation and evolution of the early Solar System. Grove Mountains (GRV) CM chondrites have been collected from Antarctica by Chinese Antarctic Research Expedition (CARE) for nearly 20 years.

  • CM chondrite
  • Grove Mountains
  • CAIs
  • GRV 020025

1. Introduction

Carbonaceous chondrites (CCs) are fragments of hydrated asteroids and among the oldest and most primitive objects that provide insights into the early protoplanetary disk, the formation of the planets and the origin of water and life [1][2][3]. The major chemical groups of CCs include the Ivuna-type (CI), Mighei-type (CM), Ornans-type (CO), Vigarano-type (CV), Karoonda-type (CK), Renazzo-type (CR), Bencubbin-type (CB), ALH 85085-type (CH) and Loongana-type (CL) [4][5]. The CM chondrites are of particular interest, as they are the most abundance group of CCs and are the material most frequently found as clasts within other types of meteorites [6][7]. This suggests that the CM parent asteroids are (or were) widespread in the asteroid belt, including the regions providing samples to Earth [8]. Up to date (1 February 2022), there are 715 pieces of CM chondrites according to Meteoritical Bulletin Database [9], accounting for about 25% of the total CCs and approximately 0.9% of all the officially named meteorites.
Antarctica is a cold and dry continent covered with ice and snow. Thus, it is a wonderful place to preserve and collect meteorites. Now, there are 1339 pieces of CCs found by Antarctic scientific expedition teams sent by various countries that occupied 47% of the total CCs. The proportion of CM chondrites is the highest, which is much higher than other types of CCs, reaching about 42% (564 pieces) out of the total Antarctic CCs. Thus, Antarctica is the most important enrichment site of CM-type meteorites.
In the last years, Grove Mountains was selected as an area of high meteorite concentration in Antarctica. Since the first expedition in 1998, 12,665 pieces of meteorites have been collected by CARE in this region and China has been one of the biggest owners of Antarctic meteorites [10].

2. Sample Description

The CM chondrite samples include GRV 020005, GRV 020017, GRV 020025, GRV 021536, GRV 021580, GRV 050179, GRV 050384 and GRV 13051 collected from Grove Mountains, Antarctica. Among these samples, GRV 020025 is the most intensively studied by several researchers (Table 1). All these samples are relatively small in weight with mass ranging from 0.4 to 5 g. The samples are black irregular fragments. They are relatively fresh. Some of them are almost completely covered by black fusion crust (Figure 1C,D) and others are only partially covered (Figure 1A,B).
Figure 1. Typical specimens of CM chondrites in Grove Mountains, Antarctica: (A) GRV 020005; (B) GRV 020017; (C) GRV 020025; (D) GRV 050179.
Table 1. General information of CM chondrites found in Grove Mountains, Antarctica.

3. Petrology and Mineralogy

3.1. General Description

In these GRV CM chondrites, four samples (GRV 020005, GRV 020017, GRV 020025 and GRV 050179) were studied in relative detail (Table 1 and Table 2). Dai [14] first investigated the thin sections of GRV 020017 and GRV 020025. Several years later, Wang [15] observed new slices of these samples. In general, the GRV CM chondrites show similar petrographic properties of average CM chondrites [19] in chondrule/matrix abundance and size distribution (Table 2). The relative low CAI and AOA and high sulfide abundance probably resulted from the heterogeneous sampling on parent body and (or) selective alteration. Statistical error may sometimes be a possible factor leading to different results, especially in measuring the low content indicators (such as sulfide, metal and CAIs, Table 2). According to the published data by Shen et al. [20], GRV 020025 has a CAI content of up to 1.0%, which is much close to the average value of the CM chondrites (1.2%). The sample of GRV 020005 is quite different from other samples in chondrule size and content (low) and matrix content (high) which just shows the CM1 petrologic type [15].
Table 2. Summary of average petrographic properties of the GRV CM chondrites.
*: data from [11]; **: data acquired by backscatter image from [11]; $: data from [12]; #: data from [20]; $$: data from [18]; ##: data from [19]; &: data from [13]. Chd: chondrule; Chd Dia: chondrule diameter; CAIs: calcium, aluminum-rich inclusions.
The petrological and mineralogical characteristics of GRV 020017and GRV 020025 are similar, mainly composed of opaque matrix and a small amount of high-temperature components (including chondrule, CAIs and crystal clast) with fine-grained rims. Electron microprobe analysis on olivine and pyroxene in the chondrule and matrix of GRV 020017 and GRV 020025 shows that they have similar mineral composition patterns. The values of olivine Fa, low-Ca pyroxene Fs, En and Wo are summed up in Table 3. The chemical composition of olivine and pyroxene is very heterogeneous as indicated by the high PMD value (>>5, Table 3) [11][12][13][16]. It is noteworthy that the chemical composition of olivine in the chondrules of GRV 020025 is relatively uniform (Fa: 0.8–1.1 with one exception of 4.7) [12] while it varies largely in the olivine clasts (Fa: 0.6–48.3) [13].
Table 3. Mineral composition of olivine and pyroxene in GRV 020017 and GRV 020025.

*: data of matrix olivine and pyroxene. Fa: fayalite. PMD: percent mean deviations. Fs: ferrosilite. En: enstatite. Wo: wollastonite.

3.2. Matrix

Matrix material is best defined as the optically opaque mixture of mineral grains 10 nm to 5 mm in size distinguishing from fragments of chondrules, CAIs and other components by their distinctive sizes, shapes and textures [19]. So far, Professor Miao Bingkui’s team [11][13] has carefully studied the matrix of three GRV CM chondrites (GRV 02005, GRV 020017 and GRV 020025). The matrix is mainly divided into three types of interstitial matrix, fine-grained rim (FGR) and dark inclusions (DIs).

3.3. CAIs

CAIs were found in almost all GRV CM chondrites when they were reported to the International Society for Meteoritics and Planetary Science [9]. However, in-depth researches on CAIs (petrology and mineral chemistry) were only carried out in the samples of GRV 020025 and GRV 050179 [12][14][15][16][18][20].

This entry is adapted from the peer-reviewed paper 10.3390/min12050619

References

  1. Halliday, A.N. 2.8—The origin and earliest history of the Earth. In Treatise on Geochemistry, 2nd ed.; Holland, H.D., Turekian, K.K., Eds.; Elsevier: Oxford, UK, 2014; pp. 149–211.
  2. Gilmour, I. 1.5—Structural and isotopic analysis of organic matter in carbonaceous chondrites. In Treatise on Geochemistry, 2nd ed.; Holland, H.D., Turekian, K.K., Eds.; Elsevier: Oxford, UK, 2014; pp. 215–233.
  3. Martins, Z.; Chan, Q.H.S.; Bonal, L.; King, A.; Yabuta, H. Organic matter in the Solar System—Implications for future on-site and sample return missions. Space Sci. Rev. 2020, 216, 54.
  4. Weisberg, M.K.; McCoy, T.J.; Krot, A.N.; Binzel, R.P.; Walker, R.M.; Cameron, A.G.W. Systematics and evaluation of meteorite classification. In Meteorites and the Early Solar System II; Lauretta, D.S., McSween, H.Y., Eds.; University of Arizona Press: Tucson, AZ, USA, 2006; pp. 19–52.
  5. Metzler, K.; Hezel, D.C.; Barosch, J.; Wölfer, E.; Schneider, J.M.; Hellmann, J.L.; Berndt, J.; Stracke, A.; Gattacceca, J.; Greenwood, R.C.; et al. The Loongana (CL) group of carbonaceous chondrites. Geochim. Cosmochim. Acta 2021, 304, 1–31.
  6. Zolensky, M.E.; Weisberg, M.K.; Buchanan, P.C.; Mittlefehldt, D.W. Mineralogy of carbonaceous chondrite clasts in HED achondrites and the Moon. Meteorit. Planet. Sci. 1996, 31, 18–537.
  7. Lunning, N.G.; Corrigan, C.M.; McSween, H.Y.; Tenner, T.J.; Kita, N.T.; Bodnar, R.J. CV and CM chondrite impact melts. Geochim. Cosmochim. Acta 2016, 189, 38–358.
  8. Zolensky, M.E.; Mittlefehldt, D.W.; Lipschutz, M.E.; Wang, M.-S.; Clayton, R.N.; Mayeda, T.K.; Grady, M.M.; Pillinger, C.; David, B. CM chondrites exhibit the complete petrologic range from type 2 to 1. Geochim. Cosmochim. Acta 1997, 61, 5099–5115.
  9. Meteoritical Bulletin: Search for the Meteoritical Bulletin Database. Available online: https://www.lpi.usra.edu/meteor/ (accessed on 1 February 2022).
  10. Miao, B.; Hu, S.; Chen, H.; Zhang, C.; Xia, Z.; Huang, L.; Xue, Y.; Xie, L. Progresses of researches on meteoritics and cosmochemistry from 2011 to 2020 in China. Bull. Mineral. Petrol. Geochem. 2021, 40, 1–15, (In Chinese with English abstract).
  11. Wang, X. Study on the Petrology and Origin of Matrix of Antarctic Carbonaceous Chondrites. Master’s Thesis, Guilin University of Technology, Guilin, China, 2009. (In Chinese).
  12. Dai, D. Classification of 104 Meteorites Collected in Grove Mountains, Antarctic, and a Comparative Study of Ca, Al-Rich Inclusions (CAIs) from Various Groups of Chondrites. Ph.D. Thesis, School of the Chinese Academy of Sciences, Guangzhou, China, 2007. (In Chinese).
  13. Miao, B. Comprehensive Study of Meteorites from Grove Mountains, Antarctica. Postdoctoral Research Report; Institute of Geology and Geophysics, Chinese Academy of Sciences: Beijing, China, 2008. (In Chinese)
  14. Dai, D.; Lin, Y.; Miao, B.; Shen, W.; Wang, D. Ca-, Al-rich inclusions in three new carbonaceous chondrites from the Grove Mountains, Antarctica: New evidence for a similar origin of the objects in various groups of chondrites. Acta Geol. Sin. 2004, 78, 1042–1051.
  15. Dai, D.; Wang, D. Petrography and mineral chemistry of 4 carbonaceous chondrites from the Grove Mountains, Antarctica. Chin. J. Polar Res. 2009, 20, 166–171.
  16. Dai, D.; Chen, X.; Yang, R. The study of and expectations for finding carbonaceous chondrites in the Grove Mountains, Antarctica. Chin. J. Polar Res. 2013, 25, 378–385. (In Chinese)
  17. Zhang, A.C.; Itoh, S.; Yurimoto, H.; Hsu, W.B.; Wang, R.C.; Taylor, L.A. P-O-rich sulfide phase in CM chondrites: Constraints on its origin on the CM parent body. Meteorit. Planet. Sci. 2016, 51, 56–69.
  18. Dai, D.; Zhou, C.; Chen, X. Ca-, Al-rich inclusions in two new carbonaceous chondrites from Grove Mountains, Antarctica. Earth Moon Planets 2015, 115, 101–114.
  19. Scott, E.R.D.; Krot, A.N. 1.2—Chondrites and their components. In Treatise on Geochemistry, 2nd ed.; Holland, H.D., Turekian, K.K., Eds.; Elsevier: Oxford, UK, 2014; pp. 65–137.
  20. Shen, W.; Miao, B.; Lin, Y. A fine study on petrology and mineralogy of carbonaceous chondrite GRV 020025. In Proceedings of the 10th National Symposium on Lunar Science, Comparative Planetary, Meteorology and Cosmochemistry, Guilin, China, 24 October 2012; p. 45.
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