materials science Materials science is an interdisciplinary field of researching and discovering materials. Materials engineering is an engineering field of finding uses for materials in other fields and industries. The intellectual origins of materials sci ...

, Schmid's law (also Schmid factor) states that slip begins in a crystalline material when the resolved

shear stress Shear stress (often denoted by , Greek alphabet, Greek: tau) is the component of stress (physics), stress coplanar with a material cross section. It arises from the shear force, the component of force vector parallel to the material cross secti ...

on a slip system reaches a critical value, known as the critical resolved shear stress. Schmid factor schematic

A slip system can be described by two vectors: a vector normal to the slip plane and a vector parallel to the slip direction. The resolved shear stress on a slip system (

\tau

) is given by

\tau = \sigma \cos\phi \cos\lambda

, where

\sigma

is the magnitude of the applied tensile stress,

\phi

is the angle between the slip plane normal and the direction of the applied stress, and

\lambda

is the angle between the slip direction and the direction of the applied stress. This equation can also be expressed in terms of the Schmid factor (

m

), given by

m = \cos\phi \cos\lambda

According to Schmid's law, slip begins on the slip system when

\tau = \tau_c

, where

\tau_c

is the critical resolved shear stress. The corresponding tensile stress at which slip begins is the

yield stress In materials science and engineering, the yield point is the point on a stress–strain curve that indicates the limit of elasticity (physics), elastic behavior and the beginning of plasticity (physics), plastic behavior. Below the yield point ...

(

\sigma_y

), which is related to the critical resolved shear stress by

\tau_c = m \sigma_y

. The Schmid factor is limited to the range

0 \le m \le 0.5

. The Schmid factor is minimized when the tensile stress is perpendicular to the slip plane normal (

\cos\phi = 0

) or perpendicular to the slip direction (

\cos \lambda = 0

). The Schmid factor is maximized when

\phi = \lambda = 45^\circ

. For crystals with multiple slip systems, Schmid's law indicates that the slip system with the largest Schmid factor will yield first. The Schmid factor is named after Erich Schmid who coauthored a book with Walter Boas introducing the concept in 1935.

See also

Notes

References

Further reading