Banach–Tarski paradox

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Antiplane shear or antiplane strain[1] is a special state of strain in a body. This state of strain is achieved when the displacements in the body are zero in the plane of interest but nonzero in the direction perpendicular to the plane. For small strains, the strain tensor under antiplane shear can be written as

ε=[00ϵ1300ϵ23ϵ13ϵ230]

where the 12 plane is the plane of interest and the 3 direction is perpendicular to that plane.

Displacements

The displacement field that leads to a state of antiplane shear is (in rectangular Cartesian coordinates)

u1=u2=0;u3=u^3(x1,x2)

where ui,i=1,2,3 are the displacements in the x1,x2,x3 directions.

Stresses

For an isotropic, linear elastic material, the stress tensor that results from a state of antiplane shear can be expressed as

σ[σ11σ12σ13σ12σ22σ23σ13σ23σ33]=[00μu3x100μu3x2μu3x1μu3x20]

where μ is the shear modulus of the material.

Equilibrium equation for antiplane shear

The conservation of linear momentum in the absence of inertial forces takes the form of the equilibrium equation. For general states of stress there are three equilibrium equations. However, for antiplane shear, with the assumption that body forces in the 1 and 2 directions are 0, these reduce to one equilibrium equation which is expressed as

μ2u3+b3(x1,x2)=0

where b3 is the body force in the x3 direction and 2u3=2u3x12+2u3x22. Note that this equation is valid only for infinitesimal strains.

Applications

The antiplane shear assumption is used to determine the stresses and displacements due to a screw dislocation.

References

  1. W. S. Slaughter, 2002, The Linearized Theory of Elasticity, Birkhauser

See also