Microstructural, compositional and petrophysical properties of mylonitic granodiorites from an extensional shear zone (Rhodope core complex, Greece)

At the southern boundary of the Rhodope Massif, NE Greece, the Kavala Shear Zone (KSZ) represents an example of the Eastern Mediterranean deep-seated extensional tectonic setting. During Miocene time, extensional deformation favoured syntectonic emplacement and subsequent exhumation of plutonic bodi...

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Bibliographic Details
Published in:Geological magazine 2014-11, Vol.151 (6), p.1051-1071
Main Authors: Punturo, Rosalda, Cirrincione, Rosolino, Fazio, Eugenio, Fiannacca, Patrizia, Kern, Hartmut, Mengel, Kurt, Ortolano, Gaetano, Pezzino, Antonino
Format: Article
Language:English
Subjects:
Anisotropy
body waves
Cenozoic
deformation
Elastic properties
elastic waves
emplacement
Europe
extension faults
extension tectonics
fabric
faults
foliation
Geochemistry
granodiorites
Greece
Greek Thrace
igneous and metamorphic rocks
igneous rocks
intrusions
Kavala shear zone
metamorphic core complexes
metamorphic rocks
Microstructure
mineral composition
Minerals
Miocene
mylonites
Neogene
P-waves
Petrology
physical properties
Plate tectonics
plutonic rocks
Rhodope Complex
Rhodope Greece
Rhodope Mountains
Rocks
S-waves
seismic waves
Seismology
shear zones
Southern Europe
syntectonic processes
tectonics
Tertiary
textures
Thrace
velocity
Wave velocity
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Summary:At the southern boundary of the Rhodope Massif, NE Greece, the Kavala Shear Zone (KSZ) represents an example of the Eastern Mediterranean deep-seated extensional tectonic setting. During Miocene time, extensional deformation favoured syntectonic emplacement and subsequent exhumation of plutonic bodies. This paper deals with the strain-related changes in macroscopic, geochemical and microstructural properties of the lithotypes collected along the KSZ, comprising granitoids from the pluton, aplitic dykes and host rock gneisses. Moreover, we investigated the evolution of seismic anisotropy on a suite of granitoid mylonites as a result of progressive strain. Isotropic compressional and shear wave velocities (Vp, Vs) and densities calculated from modal proportions and single-crystal elastic properties at given pressure-temperature (P-T) conditions are compared to respective experimental data including the directional dependence (anisotropy) of wave velocities. Compared to the calculated isotropic velocities, which are similar for all of the investigated mylonites (average values: Vp approximately 5.87 km s-1, Vs approximately 3.4 km s-1, Vp/Vs = 1.73 and density = 2.65 g cm-3), the seismic measurements give evidence for marked P-wave velocity anisotropy up to 6.92% (at 400 MPa) in the most deformed rock due to marked microstructural changes with progressive strain, as highlighted by the alignment of mica, chlorite minerals and quartz ribbons. The highest P- and S-wave velocities are parallel to the foliation plane and lowest normal to the foliation plane. Importantly, Vp remains constant within the foliation with progressive strain, but decreases normal to foliation. The potential of the observed seismic anisotropy of the KSZ mylonites with respect to detectable seismic reflections is briefly discussed.
ISSN:0016-7568
1469-5081
DOI:10.1017/S001675681300109X