Elasticity/Stress functions

You have probably encountered potential functions in introductory physics. Forces can often be calculated assuming the existence of a scalar potential field. One takes the derivative of the potential function with respect to spatial coordinates to get a vector field.

An example is the gravitational potential field.

Consider the gravitational force (${\displaystyle \mathbf {f} }$ ) between two masses (${\displaystyle M_{1},~M_{2}}$ ) separated by a distance ${\displaystyle r}$ .

${\displaystyle \mathbf {f} =-G~{\cfrac {M_{1}~M_{2}}{r}}~{\widehat {\mathbf {r} }}}$ 

The gravitational potential energy (${\displaystyle \textstyle U}$ ) is a scalar given by

${\displaystyle U=\mathbf {f} \bullet {\widehat {\mathbf {r} }}=-G{\cfrac {M_{1}M_{2}}{r}}}$ 

The gravitational field (${\displaystyle \textstyle \mathbf {g} }$ ) (due to the effect of many masses), at a point (per unit mass ${\displaystyle \textstyle M_{0}}$ ) is

${\displaystyle \mathbf {g} ={\cfrac {\mathbf {f} }{M_{0}}}}$ 

The gravitational potential (${\displaystyle \textstyle V}$ ) is a scalar function of position

${\displaystyle V={\cfrac {U}{M_{0}}}}$ 

The work done by the gravitational force equals the decrease in gravitational potential energy.

The scalar gravitational potential can be used to find the vector gravitational field.

${\displaystyle g_{i}=-{\cfrac {\partial V}{\partial x_{i}}}}$ 

Stress functions are very similar to other scalar potential functions such as the gravitational potential. However, instead of delivering a vector field upon differentiation, stress functions deliver a second-order tensor field.

Here are some facts about most stress functions:

• Scalar potential functions that can be used to determine the stress field.
• No obvious physical meaning other than their use in defining stress components in terms of derivatives.
• The only restriction on the choice of a stress function is that the stress components must be defined in terms of the second derivatives of a scalar.
• This is because the second derivatives of a scalar form the components of a second-order tensor.
• Why is such a restriction necessary? To preserve the rules for coordinate transformations.

Airy stress function

Introduction to Elasticity