Geology Reference
In-Depth Information
[198] Kimura, M., M. K. Weisberg, y. Lin, A. Suzuki, E.
ohtani, and R. okazaki (2005), Thermal history of the
enstatite chondrites from silica polymorphs,
Meteorit.
Planet. Sci.
,
40
, 855.
[199] Kong, P., T. Mori, and M. Ebihara (1997), Compositional
continuity of enstatite chondrites and implications for
heterogeneous accretion of the enstatite chondrite parent
body,
Geochim. Cosmochim. Acta
,
61
, 4895.
[200] Rubin, A. E., E. R. D. Scott, and K. Keil (1997), Shock
metamorphism of enstatite chondrites,
Geochim.
Cosmochim. Acta
,
61
, 847-858.
[201] Rubin, A. E., H. Huber, and J. T. Wasson (2009), Possible
impact-induced refractory-lithophile fractionations in EL
chondrites,
Geochim. Cosmochim. Acta
,
73
, 1523-1537.
[202] Schneider, D. M., P. H. Benoit, A. Kracher, and D. W. g.
Sears (2003), Metal size distributions in EH and EL
chondrites,
Geophys. Res. Lett.
,
30
, 1420.
[203] Schneider, D. M., S. J. K. Symes, P. H. Benoit, and D. W.
g.Sears (2002), Properties of chondrules in EL3 chon-
drites, comparison with EH3 chondrites, and the implica-
tions for the formation of enstatite chondrites,
Meteorit.
Planet. Sci.
,
37
, 1401-1416.
[204] Zhang, y., P. H. Benoit, and D. W. g. Sears (1995), The
classification and complex thermal history of the enstatite
chondrites,
J. Geophys. Res.
,
100
, 9417-9438.
88136 (EL3): Representatives of EH and EL parent
bodies,
Meteorit. Planet. Sci.
, 37, 577-599.
[214] Lundberg, L. L., E. Zinner, and g. Crozaz (1994), Search
for isotopic anomalies in oldhamite (CaS), from unequili-
brated (E3), enstatite chondrites,
Meteoritics
, 29, 384-393.
[215] Nakashima, D., T. Nakamura, and R. okazaki (2006),
Cosmic-ray exposure age and heliocentric distance of the
parent bodies of enstatite chondrites ALH 85119 and
MAC 88136,
Meteoritics
, 41, 851-862.
[216] Patzer, A., and L. Schultz (2001), Noble gases in enstatite
chondrites i: Exposure ages, pairing, and weathering
effects,
Meteorit. Planet. Sci.
, 36, 947-961.
[217] Patzer, A., and L. Schultz (2002), Noble gases in enstatite
chondrites ii: The trapped component,
Meteorit. Planet.
Sci.
, 37, 601-612.
[218] Quirico, E., M. Bourot-Denise, C. Robin, g. Montagnac,
and P. Beck (2011), A reappraisal of the metamorphic
history of EH3 and EL3 enstatite chondrites,
Geochim.
Cosmochim. Acta
, 75, 3088-3102.
[219] Wadhwa, M., E. K. Zinner, and g. Crozaz (1997), Mn-Cr
systematics in sulfides of unequilibrated enstatite chon-
drites,
Meteoritics
, 32, 281-292.
[220] Weisberg, M. K., and M. Kimura (2012), The unequili-
brated enstatite chondrites,
Chemie der Erde
,
72
, 101-115.
32. QUE 94368—EL4 CHoNDRiTE
31. MAC 88136—EL3 CHoNDRiTE
[221] Rubin (1997), Sinoite (Si
2
N
2
o): Crystallization from EL
chondrite impact melts.
Amer. Mineral.
, 82, 1001-1006.
[222] Rubin, A. E., E. R. D. Scott, and K. Keil (1997), Shock
metamorphism of enstatite chondrites,
Geochim.
Cosmochim. Acta
,
61
, 847-858.
[205] Bouvier, A., J. D. Vervoort, and P. J. Patchett (2008), The
Lu Hf and Sm Nd isotopic composition of CHUR:
Constraints from unequilibrated chondrites and implica-
tions for the bulk composition of terrestrial planets,
Earth Planet. Sci. Lett.
, 273, 48-57.
[206] Crozaz, g., and L. L. Lundberg (1995), The origin of
oldhamite in unequilibrated enstatite chondrites,
Geochim. Cosmochim. Acta
, 59, 3817-3831.
[207] Fagan, T. J., A. N. Krot, and K. Keil (2000), Calcium-
aluminum-rich inclusions in enstatite chondrites,
Meteorit. Planet. Sci.
, 35, 771-781.
[208] guan, y., g. R. Huss, and L. A. Leshin (2007), 60Fe 60Ni
and
53
Mn
53
Cr isotopic systems in sulfides from unequili-
brated enstatite chondrites,
Geochim. Cosmochim. Acta
,
71, 4082-4091.
[209] Hsu, W., and g. Crozaz (1998), Mineral chemistry and
the origin of enstatite in unequilibrated enstatite chon-
drites,
Geochim. Cosmochim. Acta
, 62, 1993-2004.
[210] Hsu, W. (1998), geochemical and petrographic studies of
oldhamite, diopside, and roedderite in enstatite meteor-
ites,
Meteorit. Planet. Sci.
, 33, 291-301.
[211] Lin, y., and M. Kimura (1998), Petrographic and miner-
alogical study of new EH melt rocks and a new enstatite
chondrite grouplet,
Meteorit. Planet. Sci.
, 33, 501-511.
[212] Lin, y. T., H. Nagel, L. L. Lundberg, and A. El goresy
(1991), MAC 88136: The first EL3 chondrite,
Lunar
Planet. Sci. Conf.
, 22, 811.
[213] Lin, y., and A. El goresy (2002), A comparative study of
opaque phases in Qingzhen (EH3), and MacAlpine Hills
33. LAP 02225—E CHoNDRiTE iMPACT MELT
[223] izawa, M. R. M., R. L. Flemming, N. R. Banerjee, and S.
Matveev (2011), QUE 94204: A primitive enstatite achon-
drite produced by the partial melting of an E chondrite-
like protolith, M
eteorit. Planet. Sci.
46
, 1742-1753.
34. QUE 94204—UNgRoUPED ENSTATiTE
METEoRiTE
[224] izawa, M. R. M., R. L. Flemming, N. R. Banerjee, and S.
Matveev (2011), QUE 94204: A primitive enstatite achon-
drite produced by the partial melting of an E chondrite-
like protolith,
Meteorit. Planet. Sci.
46, 1742-1753.
[225] Lin, y., and M. Kimura (1998), Petrographic and miner-
alogical study of new EH melt rocks and a new enstatite
chondrite grouplet,
Meteorit. Planet. Sci.
,
3
, 501-511.
[226] Newton, J., i. A. Franchi, and C. T. Pillinger (2000), The
oxygen isotope record in enstatite meteorites,
Meteorit.
Planet
. Sci., 35, 689-698.
[227] Patzer, A., and L. Schultz (2002), Noble gases in enstatite
chondrites ii: The trapped component,
Meteorit. Planet.
Sci.
, 37, 601-612.
