Pure shear

In mechanics and geology, pure shear is a three-dimensional homogeneous flattening of a body.[1] It is an example of irrotational strain in which body is elongated in one direction while being shortened perpendicularly. For soft materials, such as rubber, a strain state of pure shear is often used for characterizing hyperelastic and fracture mechanical behaviour.[2] Pure shear is differentiated from simple shear in that pure shear involves no rigid body rotation. [3][4]

The deformation gradient for pure shear is given by:

$F={\begin{bmatrix}1&\gamma &0\\\gamma &1&0\\0&0&1\end{bmatrix}}$

Note that this gives a Green-Lagrange strain of:

$E={\frac {1}{2}}{\begin{bmatrix}\gamma ^{2}&2\gamma &0\\2\gamma &\gamma ^{2}&0\\0&0&0\end{bmatrix}}$

Here there is no rotation occurring, which can be seen from the equal off-diagonal components of the strain tensor. The linear approximation to the Green-Lagrange strain shows that the small strain tensor is:

$\epsilon ={\frac {1}{2}}{\begin{bmatrix}0&2\gamma &0\\2\gamma &0&0\\0&0&0\end{bmatrix}}$

which has only shearing components.

References

Reish, Nathaniel E.; Gary H. Girty. "Definition and Mathematics of Pure Shear". San Diego State University Department of Geological Sciences. Retrieved 24 December 2011.
Yeoh, O. H. (2001). "Analysis of deformation and fracture of 'pure shear'rubber testpiece". Plastics, Rubber and Composites. 30 (8): 389–397. doi:10.1179/146580101101541787.
"Where do the Pure and Shear come from in the Pure Shear test?" (PDF). Retrieved 12 April 2013.
"Comparing Simple Shear and Pure Shear" (PDF). Retrieved 12 April 2013.

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[1] Reish, Nathaniel E.; Gary H. Girty. "Definition and Mathematics of Pure Shear". San Diego State University Department of Geological Sciences. Retrieved 24 December 2011.

[2] Yeoh, O. H. (2001). "Analysis of deformation and fracture of 'pure shear'rubber testpiece". Plastics, Rubber and Composites. 30 (8): 389–397. doi:10.1179/146580101101541787.

[3] "Where do the Pure and Shear come from in the Pure Shear test?" (PDF). Retrieved 12 April 2013.

[4] "Comparing Simple Shear and Pure Shear" (PDF). Retrieved 12 April 2013.

Structural geology
Underlying theory	Strain Stress Stress field Mohr–Coulomb theory Mohr's circle Lamé's stress ellipsoid Strain partitioning Tension Overburden pressure Deformation mechanism Rock mechanics
Measurement conventions	Strike and dip Rake Inclinometer Brunton compass Stereographic projection Orthographic projection
Large-Scale Tectonics	Plate tectonics Orogeny Structural basin Rift Extensional tectonics Graben Half-graben Décollement Obduction List of tectonic plate interactions Nappe Continental collision Convergent boundary Fenster Klippe Fold and thrust belt Foreland basin Accretionary wedge Terrane Mountain formation Fold mountains Fault block Horst Rift valley Mélange Thick-skinned deformation Thin-skinned deformation Thrust tectonics Passive margin Divergent boundary Back-arc basin Intra-arc basin Strike-slip tectonics Syneclise Suture Saddle Inversion Horst and graben Horse Pull-apart basin Autochthon Allochthon
Fracturing	Joint Exfoliation joint Vein Dike Columnar jointing
Faulting	Thrust fault Detachment fault Disturbance Fault mechanics Fault trace Fault scarp Transform fault Transfer zone Cataclastic rock Cataclasite
Foliation and Lineation	Rock microstructure Crenulation Cleavage Slickenside Pressure solution Stylolite Compaction Fissility Oblique foliation Tectonic phase Tectonite
Folding	Vergence Anticline Syncline Dome Monocline Chevron Homocline Detachment fold
Boudinage	Competence
Kinematic Analysis	3D fold evolution Section restoration Paleostress Paleostress inversion
Shear zone	Shear Pure shear Mylonite

Pure shear

See also

References