Cataclastic rock

A cataclastic rock is a type of fault rock that has been wholly or partly formed by the progressive fracturing and comminution of existing rocks, a process known as cataclasis. Cataclasis involves the granulation, crushing, or milling of the original rock, then rigid-body rotation and translation of mineral grains or aggregates before lithification. Cataclastic rocks are associated with fault zones and impact event breccias.

Classification

Various classification schemes have been proposed for the cataclastic rocks, but changes in understanding of the processes involved in their formation and better knowledge of the variety of such rocks has made a simple classification difficult, particularly where distinctions cannot be made in hand specimens.^[1] Sibson's 1977 classification of fault rocks was the first to include an understanding of the deformation mechanisms involved and all subsequent schemes have been based on this.^[2]^[3] Fault breccias have been further classified in terms of their origins; attrition, distributed crush and implosion brecciation,^[4] and, borrowing from the cave-collapse literature, crack, mosaic and chaotic from their clast concentration.^[5]

Mylonite was originally defined as a cataclastic rock but is now understood to have formed mainly by crystal-plastic processes.^[1]

Types

Cataclasite

Cataclasite is a fault rock that consists of angular clasts in a finer-grained matrix.^[1] It is normally non-foliated but some varieties have been described with a well-developed planar fabric that are known as foliated cataclasites.^[3] Cataclasite grades into fault breccia as the percentage of visible clasts increases to more than 30%.

Fault breccia

Fault breccia is a fault rock that consists of large fragments of rock in a fine-grained matrix. It may be either cohesive or incohesive. The matrix may also include mineral veins formed in voids between the clasts, which may themselves become fractured by later movements on the fault.

Fault gouge

Fault gouge is an unconsolidated and incohesive type of fault rock consisting almost entirely of finely crushed material. Varieties that have a large clay mineral content are known as clay gouges.

Pseudotachylite

Pseudotachylite is a fault rock that has the appearance of the basaltic glass, tachylyte. It is dark in color and has a glassy appearance. It is generally found either along a fault surface or as veins injected into the fault walls. Most pseudotachylites have clearly formed by frictional melting, associated with either seismic faulting, some large landslides or meteorite impacts.

Formation

Cataclastic rocks form by brittle processes in the upper part of the crust in areas of moderate to high strain, particularly in fault zones. The two main mechanisms involved are microfracturing (breaking the original rock into fragments) and frictional sliding/rolling of the fragments, combined with further fracturing.^[6]

Cataclastic flow

Cataclastic flow is the main deformation mechanism accommodating large strains above the brittle–ductile transition zone. It can be regarded as a ductile mechanism,^[7] although one that takes place within the elastico-frictional regime of deformation.^[2] Deformation is accommodated by the sliding and rolling of fragments within the cataclastic rock. Cycles of cementation and refracturing are generally recognised in such rocks.

References

^ a b c Brodie, K.; Fette D.; Harte B.; Schmid R. (2007-02-01). "3. Structural terms including fault rock terms" (PDF). Recommendations by the IUGS Subcommission on the Systematics of Metamorphic Rock. pp. 1–14. Retrieved 2009-11-02.
^ a b Sibson, R.H. (1977). "Fault rocks and fault mechanisms". Journal of the Geological Society. 133 (3): 191–213. Bibcode:1977JGSoc.133..191S. doi:10.1144/gsjgs.133.3.0191. S2CID 131446805. Retrieved 2009-11-03.
^ a b Lin, A. (2007). Fossil earthquakes: the formation and preservation of Pseudotachylytes. Springer. p. 348. ISBN 978-3-540-74235-7. Retrieved 2009-11-01.
^ Sibson, R.H. (1986). "Brecciation processes in fault zones: Inferences from earthquake rupturing". Pure and Applied Geophysics. 1241 (1–2): 159–175. Bibcode:1986PApGe.124..159S. doi:10.1007/BF00875724. S2CID 129350442.
^ Mort, K.; Woodcock N.H. (2008). "Quantifying fault breccia geometry: Dent Fault, NW England". Journal of Structural Geology. 30 (6): 701–709. Bibcode:2008JSG....30..701M. doi:10.1016/j.jsg.2008.02.005.
^ Blenkinsop, T. (2000). Deformation Microstructures and Mechanisms. Springer. p. 150. Archived from the original on 2013-02-03. Retrieved 2009-11-03.
^ Ismat, Z (2006). "Cataclastic flow: a means for ensuring ductility within the elastico-frictional regime". Retrieved 2009-11-03.

External links

Higgins, Michael W. (1971). Cataclastic rocks (PDF). Geological Survey Professional Paper 687. Washington, D.C: U.S. Government Printing Office.

[Kate-1] Brodie, K.; Fette D.; Harte B.; Schmid R. (2007-02-01). "3. Structural terms including fault rock terms" (PDF). Recommendations by the IUGS Subcommission on the Systematics of Metamorphic Rock. pp. 1–14. Retrieved 2009-11-02.

[Rick2-2] Sibson, R.H. (1977). "Fault rocks and fault mechanisms". Journal of the Geological Society. 133 (3): 191–213. Bibcode:1977JGSoc.133..191S. doi:10.1144/gsjgs.133.3.0191. S2CID 131446805. Retrieved 2009-11-03.

[Lin-3] Lin, A. (2007). Fossil earthquakes: the formation and preservation of Pseudotachylytes. Springer. p. 348. ISBN 978-3-540-74235-7. Retrieved 2009-11-01.

[Rick-4] Sibson, R.H. (1986). "Brecciation processes in fault zones: Inferences from earthquake rupturing". Pure and Applied Geophysics. 1241 (1–2): 159–175. Bibcode:1986PApGe.124..159S. doi:10.1007/BF00875724. S2CID 129350442.

[Nigel-5] Mort, K.; Woodcock N.H. (2008). "Quantifying fault breccia geometry: Dent Fault, NW England". Journal of Structural Geology. 30 (6): 701–709. Bibcode:2008JSG....30..701M. doi:10.1016/j.jsg.2008.02.005.

[Tom-6] Blenkinsop, T. (2000). Deformation Microstructures and Mechanisms. Springer. p. 150. Archived from the original on 2013-02-03. Retrieved 2009-11-03.

[Ismat-7] Ismat, Z (2006). "Cataclastic flow: a means for ensuring ductility within the elastico-frictional regime". Retrieved 2009-11-03.

v t e Structural geology
Underlying theory	Deformation mechanism Lamé's stress ellipsoid Mohr–Coulomb theory Mohr's circle Overburden pressure Rock mechanics Strain Strain partitioning Stress Stress field Tension
Measurement conventions	Brunton compass Inclinometer Orthographic projection Rake Stereographic projection Strike and dip
Large-scale tectonics	Accretionary wedge Allochthon Autochthon Back-arc basin Continental collision Convergent boundary Décollement Divergent boundary Extensional tectonics Fault block Fenster Fold and thrust belt Fold mountains Foreland basin Graben Half-graben Horse Horst Horst and graben Intra-arc basin Inversion Klippe List of tectonic plate interactions Mélange Mountain formation Nappe Obduction Orogeny Passive margin Plate tectonics Pull-apart basin Rift valley Rift Saddle Strike-slip tectonics Structural basin Suture Syneclise Terrane Thick-skinned deformation Thin-skinned deformation Thrust tectonics
Fracturing	Columnar jointing Dike Exfoliation joint Fissure Joint Vein
Faulting	Cataclasite Cataclastic rock Detachment fault Disturbance Fault mechanics Fault scarp Fault trace Thrust fault Transfer zone Transform fault
Foliation and lineation	Cleavage Compaction Crenulation Fissility Oblique foliation Pressure solution Rock microstructure Slickenside Stylolite Tectonic phase Tectonite
Folding	Anticline Chevron Detachment fold Dome Homocline Monocline Syncline Vergence
Boudinage	Competence
Kinematic analysis	3D fold evolution Paleostress inversion Paleostress Section restoration
Shear zone	Mylonite Pure shear Shear
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