TY - JOUR
T1 - Shearing of magma along a high-grade shear zone
T2 - Evolution of microstructures during the transition from magmatic to solid-state flow
AU - Zibra, I.
AU - Kruhl, J. H.
AU - Montanini, A.
AU - Tribuzio, R.
PY - 2012/4
Y1 - 2012/4
N2 - Syntectonic plutons may record short-lived geological events related to crustal melting and deformation of the continental crust. Therefore, interpretation of microstructure and orientation of fabrics is critical in order to constrain space/time/temperature/deformation relationships during pluton crystallization. Here we describe the transition from magmatic to solid-state deformation in the late-Variscan Diorite-Granite Suite (DGS) emplaced along the Santa Lucia Shear Zone. The systematic collection of meso-, microstructural and quartz < c > axis data allow us to examine the spatial distribution and the mode of superposition of different fabrics. We identify three magmatic microfabric types, thought to reflect the microstructural evolution at decreasing melt content during pluton crystallization. Our data suggest that diffusion creep, dislocation creep and grain-scale fracturing cooperated in accommodating the shearing of the partially molten quartzofeldspathic aggregate. We suggest tat the switch from upward to horizontal magmatic flow occurred at melt fractions gt; ~0.40, and that most of the hypersolidus fabrics formed during horizontal flow, reflecting the stress field imposed by the shear zone, and preserving no memory of the ascent stage.
AB - Syntectonic plutons may record short-lived geological events related to crustal melting and deformation of the continental crust. Therefore, interpretation of microstructure and orientation of fabrics is critical in order to constrain space/time/temperature/deformation relationships during pluton crystallization. Here we describe the transition from magmatic to solid-state deformation in the late-Variscan Diorite-Granite Suite (DGS) emplaced along the Santa Lucia Shear Zone. The systematic collection of meso-, microstructural and quartz < c > axis data allow us to examine the spatial distribution and the mode of superposition of different fabrics. We identify three magmatic microfabric types, thought to reflect the microstructural evolution at decreasing melt content during pluton crystallization. Our data suggest that diffusion creep, dislocation creep and grain-scale fracturing cooperated in accommodating the shearing of the partially molten quartzofeldspathic aggregate. We suggest tat the switch from upward to horizontal magmatic flow occurred at melt fractions gt; ~0.40, and that most of the hypersolidus fabrics formed during horizontal flow, reflecting the stress field imposed by the shear zone, and preserving no memory of the ascent stage.
KW - Axis fabrics
KW - Crustal-scale shear zone
KW - Microfabric
KW - Quartz <c>
KW - SynMagmatic deformation
KW - Syntectonic granite
UR - http://www.scopus.com/inward/record.url?scp=84858151681&partnerID=8YFLogxK
U2 - 10.1016/j.jsg.2012.01.011
DO - 10.1016/j.jsg.2012.01.011
M3 - Article
AN - SCOPUS:84858151681
SN - 0191-8141
VL - 37
SP - 150
EP - 160
JO - Journal of Structural Geology
JF - Journal of Structural Geology
ER -