Antarctic Meteorite Petrographic Description

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Sample Petrographic Description

Sample Number

LAP 02206

Newsletter

26,2

Location

LaPaz Ice Field

Field Number

15504

Dimensions (cm)

9.5 x 7.5 x 8.0

Weight (g)

1284.60

Original Classification

CV3 Chondrite

Updated Classification

CV 3.7 Chondrite Oxidized A

Pairing

LAP 02206; LAP 02228; LAP 04843;

Mineral Composition (%Fa & %Fs)

Fayalite (mol%): 0-46;Ferrosilite (mol%): 1-2

Weathering

Fracturing

Macroscopic Description - Kathleen McBride

The exteriors of these meteorites are covered with a rough, black fusion with polygonal fractures. The interior reveals a medium to dark gray matrix with white, irregularly shaped inclusions. A few dark crystalline clasts are present. Chrondrules are mm sized and are gray or rust in color.

Thin Section Description (,5) - Tim McCoy, Linda Welzenbach

The sections are so similar that a single description suffices. The sections exhibit large chondrules (up to 3 mm) and CAIs in a dark matrix with minor metal and sulfide. Olivines range from Fa_0-45, with many Fa_0-5, and pyroxenes from Fs_0-2. The meteorites are CV3 chondrites.

Reclassification Notes (AMN 46,1)

Reclassification and pairing based on Raman spectroscopy (petrologic type 3.7), and on Ni content of metal and sulfide and magnetic susceptibility (Oxidized A). Details are reported in Righter et al. (2022); doi: 10.1111/maps.13932.

Antarctic Meteorite Images for Sample LAP 02206

Field Photo(s) :

ANSMET LAP 02206 - Field Number: 15504, NASA Photo Number: jsc2018e102906

ANSMET LAP 02206 - Field Number: 15504, NASA Photo Number: jsc2018e102907

Field photo image(s) courtesy of the ANSMET (ANtarctic Search for METeorites) Program, Case Western Reserve University and the University of Utah

Antarctic Meteorite Images for Sample LAP 02206

Lab Photo(s) :

Antarctic Meteorite Images for Sample LAP 02206

Thin Section Photo(s) :

Thin Section Photo of Sample LAP 02206 in Cross-Polarized Light with 20X Magnification

Thin Section Photo of Sample LAP 02206 in Plane-Polarized Light with 20X Magnification

Thin Section Photo of Sample LAP 02206 in Reflected Light with 20X Magnification

Antarctic Meteorite Scans for Sample LAP 02206

XCT Scan(s) :

XCT Scan of Sample LAP 02206

References for Sample LAP02206

Bekaert, D.V., Curtice, J., Meier, M.M.M., Byrne, D.J., Broadley, M.W., Seltzer, A., Barry, P., Kurz, M.D., and Nielsen, S.G., 2022, Determining the noble gas cosmic ray exposure ages of 23 meteorites (8 chondrites and 15 achondrites) from modeling and empirical methods, Meteoritics & Planetary Science, 57:8, 1-28, doi:10.1111/maps.13887.

Yesiltas, M., Kebukawa, Y., Glotch, T.D., Zolensky, M., Fries, M., Aysal, N., Tukel, F.S., 2022, Compositional and spectroscopic investigation of three ungrouped carbonaceous chondrites, Meteoritics & Planetary Science, 57:9, 1665-1687, doi: 10.1111/maps.13893.

Eschrig, J., Bonal, L., Beck, P., Prestgard, T.J., 2021, Spectral reflectance analysis of type 3 carbonaceous chondrites and search for their asteroidal parent bodies. Icarus, 354, 114034, https://doi.org/10.1016/j.icarus.2020.114034.

Yesiltas, M., Young, J., Glotch, T., 2021, Thermal metamorphic history of Antarctic CV3 and CO3 chondrites inferred from the first- and second-order Raman peaks of polyaromatic organic carbon. American Mineralogist, 106, 506-517, doi: 10.2138/am-2021-7507.

Beck, P, Schmitt, B., Potin, S., Pommerol, A., and Brissaud,O., 2020, Low-phase spectral reflectance and equivalent "geometric albedo" of meteorites powders. Icarus, 354, 114066.

Bonal, L., Gattacceca, J., Garenne, A., Eschrig, J., Rochette, P., and Ruggiu, L.K., 2020, Water and heat: New constraints on the evolution of the CV chondrite parent body. Geochimica et Cosmochimica Acta, 276, 363–383.

Gattacceca, J., Bonal, L., Sonzogni, C., and Longerey, J., 2020, CV Chondrites: More than one parent body. Earth and Planetary Science Letters, 547, 116467, doi: 10.1016/j.epsi2020.116467.

Glavin, D.P., Burton, A.S., Elsila, J.E., Aponte, J.C., and Dworkin, J.P., 2020, The search for chiral asymmetry as a potential biosignature in our solar system. Chemical Reviews, 120, 4660-4689, doi: 10.1021/acs.chemrev9b00474.

Aponte, J. C., Woodward, H. K., Abreu, N. M., Elsila, J. E., & Dworkin, J. P., 2019, Molecular distribution, 13C-isotope, and enantiomeric compositions of carbonaceous chondrite monocarboxylic acids. Meteoritics & Planetary Science 54, 415-430.

Jogo, K., Ito, M., Wakita, S., Kobayashi, S., & Lee, J. I., 2019, Origin of the metamorphosed clasts in the CV 3 carbonaceous chondrite breccias of Graves Nunataks 06101, Vigarano, Roberts Massif 04143, and Yamato-86009. Meteoritics & Planetary Science, 54, 1133-1152.

Nielsen, S. G., Auro, M., Righter, K., Davis, D., Prytulak, J., Wu, F., & Owens, J. D., 2019, Nucleosynthetic vanadium isotope heterogeneity of the early solar system recorded in chondritic meteorites. Earth and Planetary Science Letters, 505, 131-140.

Simkus, D. N., Aponte, J. C., Elsila, J. E., Parker, E. T., Glavin, D. P., & Dworkin, J. P., 2019, Methodologies for Analyzing Soluble Organic Compounds in Extraterrestrial Samples: Amino Acids, Amines, Monocarboxylic Acids, Aldehydes, and Ketones. Life, 9, 47.

Aponte, J. C., Abreu, N. M., Glavin, D. P., Dworkin, J. P., & Elsila, J. E., 2017, Distribution of aliphatic amines in CO, CV, and CK carbonaceous chondrites and relation to mineralogy and processing history. Meteoritics & Planetary Science, 52, 2632–2646, doi: 10.1111/maps.12959.

Bonal, L., Quirico, E., Flandinet, L., Montagnac, G., 2016, Thermal history of type 3 chondrites from the Antarctic meteorite collection determined by Raman spectroscopy of their polyaromatic carbonaceous matter. Geochimica et Cosmochimica Acta, 189, 312-337.

Wasson, J. T., Isa, J., Rubin, A. E., 2013, Compositional and petrographic similarities of CV and CK chondrites: A single group with variations in textures and volatile concentrations attributable to impact heating, crushing and oxidation. Geochimica et Cosmochimica Acta, 108, 1-May-13, 45-62, ISSN 0016-7037, http://dx.doi.org/10.1016/j.gca.2013.01.011.

Ishida, H., Nakamura, T., Miura, H., Kakazu, Y., 2012, Diverse mineralogical and oxygen isotopic signatures recorded in CV3 carbonaceous chondrites. Polar Science, 6 Issues 3-4, August-November 2012, 252-262, ISSN 1873-9652, http://dx.doi.org/10.1016/j.polar.2012.06.002.

Burton, A. S., Elsila, J. E., Callahan, M. P., Martin, M. G., Glavin, D. P., Johnson, N. M., Dworkin, J. P., 2012, A propensity for n-ω-amino acids in thermally altered Antarctic meteorites. Meteoritics & Planetary Science, 47, 374-386, http://dx.doi.org/10.1111/j.1945-5100.2012.01341.x.

Rochette, P., Kohout, T., Pesonen, L., Quirico, E., Sagnotti, L., Skripnik, A., Gattacceca, J., Bonal, L., Bourot-Denise, M., Chevrier, V., Clerc, J. P., Consolmagno, G., Folco, L., Gounelle, M., 2008, Magnetic classification of stony meteorites: 2. Non-ordinary chondrites. Meteoritics & Planetary Science, 43, 959-980, http://dx.doi.org/10.1111/j.1945-5100.2008.tb01092.x.

RELAB, , Reflectance Experiment Lab , catalogue of samples.

Antarctic Meteorite Petrographic Description

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