TY - JOUR
T1 - The paradox between low shock-stage and evidence for compaction in CM carbonaceous chondrites explained by multiple low-intensity impacts
AU - Lindgren, Paula
AU - Hanna, Romy D.
AU - Dobson, Katherine J.
AU - Tomkinson, Tim
AU - Lee, Martin R.
PY - 2015/1/1
Y1 - 2015/1/1
N2 - Petrographic analysis of eight CM carbonaceous chondrites (EET 96029,
LAP 031166, LON 94101, MET 01072, Murchison, Murray, SCO 06043, QUE
93005) by electron imaging and diffraction, and X-ray computed
tomography, reveals that six of them have a petrofabric defined by shock
flattened chondrules. With the exception of Murchison, those CMs that
have a strong petrofabric also contain open or mineralized fractures,
indicating that tensional stresses accompanying the impacts were
sufficient to locally exceed the yield strength of the meteorite matrix.
The CMs studied span a wide range of petrologic subtypes, and in common
with Rubin (2012) we find that the strength of their petrofabrics
increases with their degree of aqueous alteration. This correspondence
suggests that impacts were responsible for enhancing alteration,
probably because the fracture networks they formed tapped fluid
reservoirs elsewhere in the parent body. Two meteorites that do not fit
this pattern are MET 01072 and Murchison; both have a strong petrofabric
but are relatively unaltered. In the case of MET 01072, impact
deformation is likely to have postdated parent body aqueous activity.
The same may also be true for Murchison, but as this meteorite also
lacks fractures and veins, its chondrules were most likely flattened by
multiple low intensity impacts. Multiphase deformation of Murchison is
also revealed by the microstructures of calcite grains, and
chondrule-defined petrofabrics as revealed by X-ray computed tomography.
The contradiction between the commonplace evidence for
impact-deformation of CMs and their low shock stages (most belong to S1)
can be explained by most if not all having been exposed to multiple low
intensity (i.e.,
AB - Petrographic analysis of eight CM carbonaceous chondrites (EET 96029,
LAP 031166, LON 94101, MET 01072, Murchison, Murray, SCO 06043, QUE
93005) by electron imaging and diffraction, and X-ray computed
tomography, reveals that six of them have a petrofabric defined by shock
flattened chondrules. With the exception of Murchison, those CMs that
have a strong petrofabric also contain open or mineralized fractures,
indicating that tensional stresses accompanying the impacts were
sufficient to locally exceed the yield strength of the meteorite matrix.
The CMs studied span a wide range of petrologic subtypes, and in common
with Rubin (2012) we find that the strength of their petrofabrics
increases with their degree of aqueous alteration. This correspondence
suggests that impacts were responsible for enhancing alteration,
probably because the fracture networks they formed tapped fluid
reservoirs elsewhere in the parent body. Two meteorites that do not fit
this pattern are MET 01072 and Murchison; both have a strong petrofabric
but are relatively unaltered. In the case of MET 01072, impact
deformation is likely to have postdated parent body aqueous activity.
The same may also be true for Murchison, but as this meteorite also
lacks fractures and veins, its chondrules were most likely flattened by
multiple low intensity impacts. Multiphase deformation of Murchison is
also revealed by the microstructures of calcite grains, and
chondrule-defined petrofabrics as revealed by X-ray computed tomography.
The contradiction between the commonplace evidence for
impact-deformation of CMs and their low shock stages (most belong to S1)
can be explained by most if not all having been exposed to multiple low
intensity (i.e.,
U2 - 10.1016/j.gca.2014.09.014
DO - 10.1016/j.gca.2014.09.014
M3 - Article (Academic Journal)
SN - 0016-7037
VL - 148
SP - 159
EP - 178
JO - Geochimica et Cosmochimica Acta
JF - Geochimica et Cosmochimica Acta
ER -