Extensional tectonics

Extensional tectonics is concerned with the structures formed by, and the tectonic processes associated with, the stretching of a planetary body's crust or lithosphere.

Deformation styles

The types of structure and the geometries formed depend on the amount of stretching involved. Stretching is generally measured using the parameter β, known as the beta factor, where

t0 is the initial crustal thickness and t1 is the final crustal thickness. It is also the equivalent of the strain parameter stretch.[1]

Low beta factor

In areas of relatively low crustal stretching, the dominant structures are high to moderate angle normal faults, with associated half grabens and tilted fault blocks.[2]

High beta factor

In areas of high crustal stretching, individual extensional faults may become rotated to too low a dip to remain active and a new set of faults may be generated.[3] Large displacements may juxtapose syntectonic sediments against metamorphic rocks of the mid to lower crust and such structures are called detachment faults. In some cases the detachments are folded such that the metamorphic rocks are exposed within antiformal closures and these are known as metamorphic core complexes.[4]

Passive margins

Passive margins above a weak layer develop a specific set of extensional structures. Large listric regional faults dipping towards the ocean develop with rollover anticlines and related crestal collapse grabens. On some margins, such as the Niger Delta, large counter-regional faults are observed, dipping back towards the continent, forming large grabenal mini-basins with antithetic regional faults.[5]

Geological environments associated with extensional tectonics

Areas of extensional tectonics are typically associated with:

Horst and graben structure, typical rift related structure (direction of extension shown by red arrows).

Continental rifts

Rifts are linear zones of localized crustal extension. They range in width from somewhat less than 100 km up to several hundred km, consisting of one or more normal faults and related fault blocks.[2] In individual rift segments, one polarity (i.e. dip direction) normally dominates, giving a half-graben geometry.[6] Other common geometries include metamorphic core complexes and tilted blocks. Examples of active continental rifts are the Baikal Rift Zone and the East African Rift.

Divergent plate boundaries

Divergent plate boundaries are zones of active extension as the crust newly formed at the mid-ocean ridge system becomes involved in the opening process.

Gravitational spreading of zones of thickened crust

Zones of thickened crust, such as those formed during continent-continent collision tend to spread laterally; this spreading occurs even when the collisional event is still in progress.[7] After the collision has finished the zone of thickened crust generally undergoes gravitational collapse, often with the formation of very large extensional faults. Large-scale Devonian extension, for example, followed immediately after the end of the Caledonian orogeny particularly in East Greenland and western Norway.[8][9]

Releasing bends along strike-slip faults

When a strike-slip fault is offset along strike such as to create a gap e.g. a left-stepping bend on a sinistral fault, a zone of extension or transtension is generated. Such bends are known as releasing bends or extensional stepovers and often form pull-apart basins or rhombochasms. Examples of active pull-apart basins include the Dead Sea, formed at a left-stepping offset of the sinistral sense Dead Sea Transform system, and the Sea of Marmara, formed at a right-stepping offset on the dextral sense North Anatolian Fault system.[10]

Back-arc basins

Back-arc basins form behind many subduction zones due to the effects of oceanic trench roll-back which leads to a zone of extension parallel to the island arc.

Passive margins

A passive margin built out over a weaker layer, such as an overpressured mudstone or salt, tends to spread laterally under its own weight. The inboard part of the sedimentary prism is affected by extensional faulting, balanced by outboard shortening.

See also

References

  1. Park, R. G. (1997). Foundations of Structural Geology (3rd ed.). Psychology Press. p. 64. ISBN 978-0-7487-5802-9.
  2. Kearey, P.; Klepeis, K.A.; Vine, F.J. (2009). "Continental rifts and rifted margins". Global Tectonics. WileyBlackwell. p. 153. ISBN 978-1-4443-0322-3.
  3. Proffett, John M. (1977). "Cenozoic geology of the Yerington district, Nevada, and implications for the nature and origin of Basin and Range faulting". Geological Society of America Bulletin. 88 (2): 247. Bibcode:1977GSAB...88..247P. doi:10.1130/0016-7606(1977)88<247:CGOTYD>2.0.CO;2.
  4. Lister, G.S.; Davis, G.A. (1989). "The origin of metamorphic core complexes and detachment faults formed during Tertiary continental extension in the northern Colorado River region, U.S.A." (PDF). J. Struct. Geol. 11 (1–2): 65–94. Bibcode:1989JSG....11...65L. doi:10.1016/0191-8141(89)90036-9.
  5. Tuttle, M.L.W., Charpentier, R.R. & Brownfield, M.E. 2002. The Niger Delta Petroleum System: Niger Delta Province, Nigeria, Cameroon, and Equatorial Guinea, Africa. USGS Open-File Report 99-50-H.
  6. White, R. S.; Hardman, R. F. P.; Watts, A. B.; Whitmarsh, R. B.; Ebinger, C. J.; Jackson, J. A.; Foster, A. N.; Hayward, N. J. (15 April 1999). "Extensional basin geometry and the elastic lithosphere". Philosophical Transactions of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences. 357 (1753): 741–765. Bibcode:1999RSPTA.357..741E. doi:10.1098/rsta.1999.0351. JSTOR 55068. S2CID 91719117.
  7. Ji, Zhou; Tonglin, Han; Armijo, R.; Mercier, J. L.; Tapponnier, P. (December 1981). "Field evidence for active normal faulting in Tibet". Nature. 294 (5840): 410–414. Bibcode:1981Natur.294..410T. doi:10.1038/294410a0. ISSN 1476-4687. S2CID 4326485.
  8. Dunlap, J. W.; Fossen, H. (1998). "Early Paleozoic orogenic collapse, tectonic stability, and late Paleozoic continental rifting revealed through thermochronology of K-feldspars, southern Norway" (PDF). Tectonics. 17 (4): 604–620. Bibcode:1998Tecto..17..604D. doi:10.1029/98TC01603.
  9. Hartz, E. H.; Andresen, A.; Hodges, K. V.; Martin, M. W. (July 2000). "U–Pb and 40Ar/39Ar constraints on the Fjord Region Detachment Zone: A long-lived extensional fault in the central East Greenland Caledonides" (PDF). Journal of the Geological Society. 157 (4): 795–809. Bibcode:2000JGSoc.157..795H. doi:10.1144/jgs.157.4.795. S2CID 130773289. Archived from the original (PDF) on 2012-03-02.
  10. Armijo, R.; Meyer, B.; Navarro, S.; King, G.; Barka, A. (2002), "Asymmetric slip partitioning in the Sea of Marmara pull-apart: a clue to propagation processes of the North Anatolian Fault?" (PDF), Terra Nova, Wiley-Blackwell, 14 (2): 80–86, Bibcode:2002TeNov..14...80A, CiteSeerX 10.1.1.546.4111, doi:10.1046/j.1365-3121.2002.00397.x, S2CID 49553634
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