Transtension

Transtension is the state in which a rock mass or area of the Earth's crust experiences both extensive and transtensive shear. As such, transtensional regions are characterised by both extensional structures (normal faults, grabens) and wrench structures (strike-slip faults). In general, many tectonic regimes that were previously defined as simple strike-slip shear zones are actually transtensional. It is unlikely that a deforming body will experience 'pure' extension or 'pure' strike-slip.

Transtensional shear zones are characterized by the co-existence of different structures, related to both strike-slip shear and extension. End member structures include pure strike-slip faults and purely extensional ("normal") dip-slip faults. Faults which have components of both (termed 'oblique' slip faults) are abundant.

Releasing bend edit

Diagram of fault geometry (in map view) that leads to transtension at the bend or step-over.

Releasing bends are transtensional structures that form where the orientation of a strike-slip fault becomes oblique to the regional slip vector causing local extension (such as a right stepping bend on a right-lateral fault).^[1] They also form where two segments of a strike-slip fault overlap, and the relay zone between the segments experiences transtension. Releasing bends often form negative flower structures or pull-apart basins. Geologists may also refer to a releasing bend as a right bend.

Transtensional regions edit

Dead Sea^[2]
Salton Sea^[2]
Sea of Marmara on the North Anatolian Fault^[3]
Vienna Basin^[4]

References edit

^ Crowell, J.C. 1974. Origin of Late Cenozoic Basins in Southern California, in Dickinson, W.R., ed., Tectonics and Sedimentation: Society of Economic Paleontologists and Mineralogists Special Publication No. 22.
^ ^a ^b Kearey, Philip and Frederick J. Vine, Global Tectonics, Blackwell Science, 2nd ed., 1996, pp. 131-133 ISBN 0-86542-924-3
^ Armijo, R.; Meyer B.; Navarro S.; King G.; Narka 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. 14 (2): 80–86. CiteSeerX 10.1.1.546.4111. doi:10.1046/j.1365-3121.2002.00397.x.
^ Royden, Leigh H., The Vienna Basin: a Thin-Skinned Pull-Apart Basin in N. Christie-Blick and K.T. Biddle (eds.), Strike-Slip Deformation, Basin Formation, and Sedimentation. SEPM Special Publications, 37.

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[1] Crowell, J.C. 1974. Origin of Late Cenozoic Basins in Southern California, in Dickinson, W.R., ed., Tectonics and Sedimentation: Society of Economic Paleontologists and Mineralogists Special Publication No. 22.

[Kearey_1996,_pp._131-133-2] Kearey, Philip and Frederick J. Vine, Global Tectonics, Blackwell Science, 2nd ed., 1996, pp. 131-133 ISBN 0-86542-924-3

[Armijo-3] Armijo, R.; Meyer B.; Navarro S.; King G.; Narka 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. 14 (2): 80–86. CiteSeerX 10.1.1.546.4111. doi:10.1046/j.1365-3121.2002.00397.x.

[4] Royden, Leigh H., The Vienna Basin: a Thin-Skinned Pull-Apart Basin in N. Christie-Blick and K.T. Biddle (eds.), Strike-Slip Deformation, Basin Formation, and Sedimentation. SEPM Special Publications, 37.

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Transtension

Contents

Releasing bend edit

Transtensional regions edit

See also edit

References edit