Geology Reference
In-Depth Information
22. MiL 05082—CB
b
CHoNDRiTE
[119] Hiroi, T., C. M. Pieters, M. E. Zolensky, and M. E.
Lipschutz (1994), Possible thermal metamorphism on the
C, g, B, and F asteroids detected from their reflectance
spectra in comparison with carbonaceous chondrites,
Proceedings of the NIPR Symposium on Antarctic
Meteorites
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[120] Huber, H., A. E. Rubin, g. W. Kallemeyn, and J. T.
Wasson (2006), Siderophile-element anomalies in CK
carbonaceous chondrites: implications for parent-body
aqueous alteration and terrestrial weathering of sulfides,
Geochim. Cosmochim. Acta
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[121] oura, y., C. Takahashi, and M. Ebihara (2004), Boron
and chlorine abundances in Antarctic chondrites: A PgA
study,
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,
17
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[122] Righter, K., and K. E. Neff (2007), Temperature and
oxygen fugacity constraints on CK and R chondrites and
implications for water and oxidation in the early solar
system,
Polar Science
,
1
, 25-44.
[123] Rubin, A. E. (1993), Magnetite-sulfide chondrules and
nodules in CK carbonaceous chondrites: implications for
the timing of CK oxidation,
Meteoritics
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28
, 30-135.
[124] Sugiura, N., and S. Zashu (1995), Nitrogen isotopic
composition of CK chondrites,
Meteoritics
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30
, 430-435.
[125] Wang, M.-S., and M. E. Lipschutz (1998), Thermally
metamorphosed carbonaceous chondrites from data for
thermally mobile trace elements,
Meteorit. Planet. Sci.
,
33
, 1297-1302.
[131] Burton, A. S., J. E. Elsila, J. E. Hein, D. P. glavin, and
J. P. Dworkin (2013), Extraterrestrial amino acids identi-
fied in metal-rich CH and CB carbonaceous chondrites
from Antarctica,
Meteorit. Planet. Sci.
48
, 390-402.
[132] Lauretta, D. S., J. S. goreva, D. H. Hill, and M. Killgore
(2007), Bulk compositions of the CB chondrites
Bencubbin, Fountain Hills, MAC 02675, and MiL 05082,
Lunar Planet. Sci. Conf.
,
38
, LPi Contribution No. 1338,
2236.
[133] Quitté, g., A. Markowski, C. Latkoczy, A. gabriel, and
A. Pack (2010), iron-60 heterogeneity and incomplete
isotope mixing in the early solar system,
Astrophys. J.
,
720
, 1215-1224.
23. gRo 95551—UNgRoUPED CHoNDRiTE
[134] Campbell, A. J., and M. Humayun (2003), Formation of
metal in grosvenor Mountains 95551 and comparison to
ordinary chondrites,
Geochim. Cosmochim. Acta
,
67
,
2481-2495.
[135] Sugiura, N., S. Zashu, M. K. Weisberg, and M. Prinz
(2000), A nitrogen isotope study of bencubbinites,
Meteorit. Planet. Sci.
,
35
, 987-996.
[136] Weisberg, M. K., M. Prinz, R. N. Clayton, T. K. Mayeda,
N. Sugiura, S. Zashu, and M. Ebihara (2001), A new
metal-rich chondrite group,
Meteorit. Planet. Sci.
,
36
,
401-418.
[137] Weisberg, M. K., T. E. Bunch, J. H. Wittke, D. Rumble,
and D. S. Ebel (2012), Petrology and oxygen isotopes of
NWA 5492, a new metal-rich chondrite,
Meteorit. Planet.
Sci.
,
47
, 363-373.
21. QUE 94411 AND 94627—CB
a
CHoNDRiTE
[126] Campbell, A. J., M. Humayun, A. Meibom, A. N. Krot,
and K. Keil (2001), origin of zoned metal grains in the
QUE94411 chondrite,
Geochim. Cosmochim. Acta
,
65
,
163-180.
[127] greshake, A., A. N. Krot, A. Meibom, M. K. Weisberg,
M. E. Zolensky, and K. Keil (2002), Heavily-hydrated
lithic clasts in CH chondrites and the related, metal-
rich chondrites Queen Alexandra Range 94411 and
Hammadah al Hamra 237,
Meteorit. Planet. Sci.
,
37
,
281-293.
[128] Krot, A. N., K. D. McKeegan, S. S. Russell, A. Meibom,
M. K. Weisberg, J. Zipfel, T. V. Krot, T. J. Fagan, and K.
Keil (2001), Refractory calcium-aluminum-rich inclu-
sions and aluminum-diopside-rich chondrules in the
metal-rich chondrites Hammadah al Hamra 237 and
Queen Alexandra Range 94411,
Meteorit. Planet. Sci.
,
36
, 1189-1216.
[129] Meibom, A., Righter, N. Chabot, g. Dehn, A. Antignano,
T. J. McCoy, A. N. Krot, M. E. Zolensky, M. i. Petaev,
and K. Keil (2005), Shock melts in QUE 94411,
Hammadah al Hamra 237, and Bencubbin: Remains of
the missing matrix,
Meteorit. Planet. Sci.
,
40
, 1377.
[130] Petaev, M. i., A. Meibom, A. N. Krot, J. A. Wood, and K.
Keil (2001), The condensation origin of zoned metal
grains in Queen Alexandra Range 94411: implications for
the formation of the Bencubbin-like chondrites,
Meteorit.
Planet. Sci.
,
36
, 93-106.
24. ALH 85085—CH CHoNDRiTE
[138] Bischoff, A., H. Palme, L. Schultz, D. Weber, H. W. Weber,
and B. Spettel (1993), Acfer 182 and paired samples, an
iron-rich carbonaceous chondrite: Similarities with
ALH 85085 and relationship to CR chondrites,
Geochim.
Cosmochim. Acta
,
57
, 2631-2648.
[139] Campbell, A. J., and M. Humayun (2004), Formation of
metal in the CH chondrites ALH 85085 and PCA 91467,
Geochim. Cosmochim. Acta
,
68
, 3409-3422.
[140] Eugster, o., and S. Niedermann (1990), Solar noble gases
in the unique chondritic breccia Allan Hills 85085,
Earth
and Planet. Sci. Letters
,
101
, 139-147.
[141] goldstein, J. i., R. H. Jones, P. g. Kotula, and J. R.
Michael (2007), Microstructure and thermal history of
metal particles in CH chondrites,
Meteorit. Planet. Sci.
,
42
, 913-933.
[142] gosselin, D. C., and J. C. Laul (1990), Chemical charac-
terization of a unique chondrite: Allan Hills 85085,
Meteoritics
,
25
, 81-87.
[143] grady, M. M., and C. T. Pillinger (1990), ALH 85085:
Nitrogen isotope analysis of a highly unusual primitive
chondrite,
Earth Planet. Sci. Letters
,
97
, 29-40.
