Constraints on the emplacement of Martian nakhlite igneous rocks and their source volcano from advanced micro‐petrofabric analysis
Constraints on the emplacement of Martian nakhlite igneous rocks and their source volcano from advanced micro‐petrofabric analysis
The Martian nakhlite meteorites, which represent multiple events that belong to a single magma source region represent a key opportunity to study the evolution of Martian petrogenesis. Here 16 of the 26 identified nakhlite specimens are studied using coupled electron backscatter diffraction (EBSD) and emplacement end-member calculations. EBSD was used to determine shape preferred orientation of contained augite (high Ca-clinopyroxene) phenocrysts by considering their crystallographic preferred orientation (CPO). Parameters derived from EBSD, and energy dispersive X-ray spectroscopy spectra were used in basic emplacement models to assess their dominant mechanism against three end-member scenarios: thermal diffusion, crystal settling, and crystal convection. Results from CPO analyses indicate low intensity weak-moderate CPO. In all samples, a consistent foliation within the <001> axes of augite are observed typically coupled with a weaker lineation CPO in one of the other crystallographic axes. These CPO results agree best with crystal settling being the dominant emplacement mechanism for the nakhlites. Modeled crystal settling results identify two distinguishable groups outside of the model's resolution indicating the presence of secondary emplacement mechanisms. Comparison of the two identified groups against CPO, geochemical, and age parameters indicate random variability between individual meteorites. Therefore, coupled CPO and emplacement modeling results identify an overarching characteristic of a dominant crystal settling emplacement mechanism for the nakhlite source volcano despite exhibiting random variation with each discharge through time.
Griffin, S.
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Daly, L.
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Keller, T.
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Piazolo, S.
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Forman, L.V.
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Lee, M.R.
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Baumgartner, R.J.
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Trimby, P.W.
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Benedix, G.K.
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Irving, A.J.
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Hoefnagels, B.
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4 June 2022
Griffin, S.
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Daly, L.
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Keller, T.
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Piazolo, S.
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Forman, L.V.
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Lee, M.R.
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Baumgartner, R.J.
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Trimby, P.W.
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Benedix, G.K.
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Irving, A.J.
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Hoefnagels, B.
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Griffin, S., Daly, L., Keller, T., Piazolo, S., Forman, L.V., Lee, M.R., Baumgartner, R.J., Trimby, P.W., Benedix, G.K., Irving, A.J. and Hoefnagels, B.
(2022)
Constraints on the emplacement of Martian nakhlite igneous rocks and their source volcano from advanced micro‐petrofabric analysis.
Journal of Geophysical Research: Planets, 127 (6), [e2021JE007080].
(doi:10.1029/2021JE007080).
Abstract
The Martian nakhlite meteorites, which represent multiple events that belong to a single magma source region represent a key opportunity to study the evolution of Martian petrogenesis. Here 16 of the 26 identified nakhlite specimens are studied using coupled electron backscatter diffraction (EBSD) and emplacement end-member calculations. EBSD was used to determine shape preferred orientation of contained augite (high Ca-clinopyroxene) phenocrysts by considering their crystallographic preferred orientation (CPO). Parameters derived from EBSD, and energy dispersive X-ray spectroscopy spectra were used in basic emplacement models to assess their dominant mechanism against three end-member scenarios: thermal diffusion, crystal settling, and crystal convection. Results from CPO analyses indicate low intensity weak-moderate CPO. In all samples, a consistent foliation within the <001> axes of augite are observed typically coupled with a weaker lineation CPO in one of the other crystallographic axes. These CPO results agree best with crystal settling being the dominant emplacement mechanism for the nakhlites. Modeled crystal settling results identify two distinguishable groups outside of the model's resolution indicating the presence of secondary emplacement mechanisms. Comparison of the two identified groups against CPO, geochemical, and age parameters indicate random variability between individual meteorites. Therefore, coupled CPO and emplacement modeling results identify an overarching characteristic of a dominant crystal settling emplacement mechanism for the nakhlite source volcano despite exhibiting random variation with each discharge through time.
Text
JGR Planets - 2022 - Griffin - Constraints on the Emplacement of Martian Nakhlite Igneous Rocks and Their Source Volcano
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Accepted/In Press date: 10 May 2022
e-pub ahead of print date: 16 May 2022
Published date: 4 June 2022
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Local EPrints ID: 488355
URI: http://eprints.soton.ac.uk/id/eprint/488355
ISSN: 2169-9100
PURE UUID: 7ee6da17-d6e6-49ee-902e-409b82e4014d
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Date deposited: 20 Mar 2024 18:14
Last modified: 21 Mar 2024 03:16
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Contributors
Author:
S. Griffin
Author:
L. Daly
Author:
T. Keller
Author:
S. Piazolo
Author:
L.V. Forman
Author:
M.R. Lee
Author:
R.J. Baumgartner
Author:
P.W. Trimby
Author:
G.K. Benedix
Author:
A.J. Irving
Author:
B. Hoefnagels
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