Neo-Hookean solid

For a compressible Ogden neo-Hookean material the Cauchy stress is given by

${\displaystyle {\boldsymbol {\sigma }}=J^{-1}{\boldsymbol {P}}{\boldsymbol {F}}^{T}=J^{-1}{\frac {\partial W}{\partial {\boldsymbol {F}}}}{\boldsymbol {F}}^{T}=J^{-1}\left(2C_{1}({\boldsymbol {F}}-{\boldsymbol {F}}^{-T})+2D_{1}(J-1)J{\boldsymbol {F}}^{-T}\right){\boldsymbol {F}}^{T}}$ 

where ${\displaystyle {\boldsymbol {P}}}$  is the first Piola–Kirchhoff stress. By simplifying the right hand side we arrive at

${\displaystyle {\boldsymbol {\sigma }}=2C_{1}J^{-1}\left({\boldsymbol {F}}{\boldsymbol {F}}^{T}-{\boldsymbol {I}}\right)+2D_{1}(J-1){\boldsymbol {I}}=2C_{1}J^{-1}\left({\boldsymbol {B}}-{\boldsymbol {I}}\right)+2D_{1}(J-1){\boldsymbol {I}}}$ 

which for infinitesimal strains is equal to

${\displaystyle \approx 4C_{1}{\boldsymbol {\varepsilon }}+2D_{1}\operatorname {tr} ({\boldsymbol {\varepsilon }}){\boldsymbol {I}}}$ 

Comparison with Hooke's law shows that ${\displaystyle C_{1}={\tfrac {\mu }{2}}}$  and ${\displaystyle D_{1}={\tfrac {\lambda _{L}}{2}}}$ .

For a compressible Rivlin neo-Hookean material the Cauchy stress is given by

${\displaystyle J~{\boldsymbol {\sigma }}=-p~{\boldsymbol {I}}+2C_{1}\operatorname {dev} ({\bar {\boldsymbol {B}}})=-p~{\boldsymbol {I}}+{\frac {2C_{1}}{J^{2/3}}}\operatorname {dev} ({\boldsymbol {B}})}$ 

where ${\displaystyle {\boldsymbol {B}}}$  is the left Cauchy–Green deformation tensor, and

${\displaystyle p:=-2D_{1}~J(J-1)~;~\operatorname {dev} ({\bar {\boldsymbol {B}}})={\bar {\boldsymbol {B}}}-{\tfrac {1}{3}}{\bar {I}}_{1}{\boldsymbol {I}}~;~~{\bar {\boldsymbol {B}}}=J^{-2/3}{\boldsymbol {B}}~.}$ 

For infinitesimal strains (${\displaystyle {\boldsymbol {\varepsilon }}}$ )

${\displaystyle J\approx 1+\operatorname {tr} ({\boldsymbol {\varepsilon }})~;~~{\boldsymbol {B}}\approx {\boldsymbol {I}}+2{\boldsymbol {\varepsilon }}}$ 

and the Cauchy stress can be expressed as

${\displaystyle {\boldsymbol {\sigma }}\approx 4C_{1}\left({\boldsymbol {\varepsilon }}-{\tfrac {1}{3}}\operatorname {tr} ({\boldsymbol {\varepsilon }}){\boldsymbol {I}}\right)+2D_{1}\operatorname {tr} ({\boldsymbol {\varepsilon }}){\boldsymbol {I}}}$ 

Comparison with Hooke's law shows that ${\displaystyle \mu =2C_{1}}$  and ${\displaystyle \kappa =2D_{1}}$ .

Proof:

The Cauchy stress in a compressible hyperelastic material is given by ${\displaystyle {\boldsymbol {\sigma }}={\cfrac {2}{J}}\left[{\cfrac {1}{J^{2/3}}}\left({\cfrac {\partial {W}}{\partial {\bar {I}}_{1}}}+{\bar {I}}_{1}~{\cfrac {\partial {W}}{\partial {\bar {I}}_{2}}}\right){\boldsymbol {B}}-{\cfrac {1}{J^{4/3}}}~{\cfrac {\partial {W}}{\partial {\bar {I}}_{2}}}~{\boldsymbol {B}}\cdot {\boldsymbol {B}}\right]+\left[{\cfrac {\partial {W}}{\partial J}}-{\cfrac {2}{3J}}\left({\bar {I}}_{1}~{\cfrac {\partial {W}}{\partial {\bar {I}}_{1}}}+2~{\bar {I}}_{2}~{\cfrac {\partial {W}}{\partial {\bar {I}}_{2}}}\right)\right]~{\boldsymbol {I}}}$  For a compressible Rivlin neo-Hookean material, ${\displaystyle {\cfrac {\partial {W}}{\partial {\bar {I}}_{1}}}=C_{1}~;~~{\cfrac {\partial {W}}{\partial {\bar {I}}_{2}}}=0~;~~{\cfrac {\partial {W}}{\partial J}}=2D_{1}(J-1)}$  while, for a compressible Ogden neo-Hookean material, ${\displaystyle {\cfrac {\partial {W}}{\partial {\bar {I}}_{1}}}=C_{1}~;~~{\cfrac {\partial {W}}{\partial {\bar {I}}_{2}}}=0~;~~{\cfrac {\partial {W}}{\partial J}}=2D_{1}(J-1)-{\cfrac {2C_{1}}{J}}}$  Therefore, the Cauchy stress in a compressible Rivlin neo-Hookean material is given by ${\displaystyle {\boldsymbol {\sigma }}={\cfrac {2}{J}}\left[{\cfrac {1}{J^{2/3}}}~C_{1}~{\boldsymbol {B}}\right]+\left[2D_{1}(J-1)-{\cfrac {2}{3J}}~C_{1}{\bar {I}}_{1}\right]{\boldsymbol {I}}}$  while that for the corresponding Ogden material is ${\displaystyle {\boldsymbol {\sigma }}={\cfrac {2}{J}}\left[{\cfrac {1}{J^{2/3}}}~C_{1}~{\boldsymbol {B}}\right]+\left[2D_{1}(J-1)-{\cfrac {2C_{1}}{J}}-{\cfrac {2}{3J}}~C_{1}{\bar {I}}_{1}\right]{\boldsymbol {I}}}$  If the isochoric part of the left Cauchy-Green deformation tensor is defined as ${\displaystyle {\bar {\boldsymbol {B}}}=J^{-2/3}{\boldsymbol {B}}}$ , then we can write the Rivlin neo-Hookean stress as ${\displaystyle {\boldsymbol {\sigma }}={\cfrac {2C_{1}}{J}}\left[{\bar {\boldsymbol {B}}}-{\tfrac {1}{3}}{\bar {I}}_{1}{\boldsymbol {I}}\right]+2D_{1}(J-1){\boldsymbol {I}}={\cfrac {2C_{1}}{J}}\operatorname {dev} ({\bar {\boldsymbol {B}}})+2D_{1}(J-1){\boldsymbol {I}}}$  and the Ogden neo-Hookean stress as ${\displaystyle {\boldsymbol {\sigma }}={\cfrac {2C_{1}}{J}}\left[{\bar {\boldsymbol {B}}}-{\tfrac {1}{3}}{\bar {I}}_{1}{\boldsymbol {I}}-{\boldsymbol {I}}\right]+2D_{1}(J-1){\boldsymbol {I}}={\cfrac {2C_{1}}{J}}\left[\operatorname {dev} ({\bar {\boldsymbol {B}}})-{\boldsymbol {I}}\right]+2D_{1}(J-1){\boldsymbol {I}}}$  The quantities ${\displaystyle p:=-2D_{1}~J(J-1)~;~~p^{*}=-2D_{1}~J(J-1)+2C_{1}}$  have the form of pressures and are usually treated as such. The Rivlin neo-Hookean stress can then be expressed in the form ${\displaystyle {\boldsymbol {\tau }}=J~{\boldsymbol {\sigma }}=-p{\boldsymbol {I}}+2C_{1}\operatorname {dev} ({\bar {\boldsymbol {B}}})}$  while the Ogden neo-Hookean stress has the form ${\displaystyle {\boldsymbol {\tau }}=-p^{*}{\boldsymbol {I}}+2C_{1}\operatorname {dev} ({\bar {\boldsymbol {B}}})}$

For an incompressible neo-Hookean material with ${\displaystyle J=1}$ 

${\displaystyle {\boldsymbol {\sigma }}=-p~{\boldsymbol {I}}+2C_{1}{\boldsymbol {B}}}$ 

where ${\displaystyle p}$  is an undetermined pressure.

For a compressible neo-Hookean hyperelastic material, the principal components of the Cauchy stress are given by

${\displaystyle \sigma _{i}=2C_{1}J^{-5/3}\left[\lambda _{i}^{2}-{\cfrac {I_{1}}{3}}\right]+2D_{1}(J-1)~;~~i=1,2,3}$ 

Therefore, the differences between the principal stresses are

${\displaystyle \sigma _{11}-\sigma _{33}={\cfrac {2C_{1}}{J^{5/3}}}(\lambda _{1}^{2}-\lambda _{3}^{2})~;~~\sigma _{22}-\sigma _{33}={\cfrac {2C_{1}}{J^{5/3}}}(\lambda _{2}^{2}-\lambda _{3}^{2})}$ 

Proof:

For a compressible hyperelastic material, the principal components of the Cauchy stress are given by ${\displaystyle \sigma _{i}={\cfrac {\lambda _{i}}{\lambda _{1}\lambda _{2}\lambda _{3}}}~{\frac {\partial W}{\partial \lambda _{i}}}~;~~i=1,2,3}$  The strain energy density function for a compressible neo Hookean material is ${\displaystyle W=C_{1}({\bar {I}}_{1}-3)+D_{1}(J-1)^{2}=C_{1}\left[J^{-2/3}(\lambda _{1}^{2}+\lambda _{2}^{2}+\lambda _{3}^{2})-3\right]+D_{1}(J-1)^{2}}$  Therefore, ${\displaystyle \lambda _{i}{\frac {\partial W}{\partial \lambda _{i}}}=C_{1}\left[-{\frac {2}{3}}J^{-5/3}\lambda _{i}{\frac {\partial J}{\partial \lambda _{i}}}(\lambda _{1}^{2}+\lambda _{2}^{2}+\lambda _{3}^{2})+2J^{-2/3}\lambda _{i}^{2}\right]+2D_{1}(J-1)\lambda _{i}{\frac {\partial J}{\partial \lambda _{i}}}}$  Since ${\displaystyle J=\lambda _{1}\lambda _{2}\lambda _{3}}$  we have ${\displaystyle \lambda _{i}{\frac {\partial J}{\partial \lambda _{i}}}=\lambda _{1}\lambda _{2}\lambda _{3}=J}$  Hence, ${\displaystyle {\begin{aligned}\lambda _{i}{\frac {\partial W}{\partial \lambda _{i}}}&=C_{1}\left[-{\frac {2}{3}}J^{-2/3}(\lambda _{1}^{2}+\lambda _{2}^{2}+\lambda _{3}^{2})+2J^{-2/3}\lambda _{i}^{2}\right]+2D_{1}J(J-1)\\&=2C_{1}J^{-2/3}\left[-{\frac {1}{3}}(\lambda _{1}^{2}+\lambda _{2}^{2}+\lambda _{3}^{2})+\lambda _{i}^{2}\right]+2D_{1}J(J-1)\end{aligned}}}$  The principal Cauchy stresses are therefore given by ${\displaystyle \sigma _{i}=2C_{1}J^{-5/3}\left[\lambda _{i}^{2}-{\cfrac {I_{1}}{3}}\right]+2D_{1}(J-1)}$

In terms of the principal stretches, the Cauchy stress differences for an incompressible hyperelastic material are given by

${\displaystyle \sigma _{11}-\sigma _{33}=\lambda _{1}~{\cfrac {\partial {W}}{\partial \lambda _{1}}}-\lambda _{3}~{\cfrac {\partial {W}}{\partial \lambda _{3}}}~;~~\sigma _{22}-\sigma _{33}=\lambda _{2}~{\cfrac {\partial {W}}{\partial \lambda _{2}}}-\lambda _{3}~{\cfrac {\partial {W}}{\partial \lambda _{3}}}}$ 

For an incompressible neo-Hookean material,

${\displaystyle W=C_{1}(\lambda _{1}^{2}+\lambda _{2}^{2}+\lambda _{3}^{2}-3)~;~~\lambda _{1}\lambda _{2}\lambda _{3}=1}$ 

Therefore,

${\displaystyle {\cfrac {\partial {W}}{\partial \lambda _{1}}}=2C_{1}\lambda _{1}~;~~{\cfrac {\partial {W}}{\partial \lambda _{2}}}=2C_{1}\lambda _{2}~;~~{\cfrac {\partial {W}}{\partial \lambda _{3}}}=2C_{1}\lambda _{3}}$ 

which gives

${\displaystyle \sigma _{11}-\sigma _{33}=2(\lambda _{1}^{2}-\lambda _{3}^{2})C_{1}~;~~\sigma _{22}-\sigma _{33}=2(\lambda _{2}^{2}-\lambda _{3}^{2})C_{1}}$ 

For a compressible material undergoing uniaxial extension, the principal stretches are

${\displaystyle \lambda _{1}=\lambda ~;~~\lambda _{2}=\lambda _{3}={\sqrt {\tfrac {J}{\lambda }}}~;~~I_{1}=\lambda ^{2}+{\tfrac {2J}{\lambda }}}$ 

Hence, the true (Cauchy) stresses for a compressible neo-Hookean material are given by

${\displaystyle {\begin{aligned}\sigma _{11}&={\cfrac {4C_{1}}{3J^{5/3}}}\left(\lambda ^{2}-{\tfrac {J}{\lambda }}\right)+2D_{1}(J-1)\\\sigma _{22}&=\sigma _{33}={\cfrac {2C_{1}}{3J^{5/3}}}\left({\tfrac {J}{\lambda }}-\lambda ^{2}\right)+2D_{1}(J-1)\end{aligned}}}$ 

The stress differences are given by

${\displaystyle \sigma _{11}-\sigma _{33}={\cfrac {2C_{1}}{J^{5/3}}}\left(\lambda ^{2}-{\tfrac {J}{\lambda }}\right)~;~~\sigma _{22}-\sigma _{33}=0}$ 

If the material is unconstrained we have ${\displaystyle \sigma _{22}=\sigma _{33}=0}$ . Then

${\displaystyle \sigma _{11}={\cfrac {2C_{1}}{J^{5/3}}}\left(\lambda ^{2}-{\tfrac {J}{\lambda }}\right)}$ 

Equating the two expressions for ${\displaystyle \sigma _{11}}$  gives a relation for ${\displaystyle J}$  as a function of ${\displaystyle \lambda }$ , i.e.,

${\displaystyle {\cfrac {4C_{1}}{3J^{5/3}}}\left(\lambda ^{2}-{\tfrac {J}{\lambda }}\right)+2D_{1}(J-1)={\cfrac {2C_{1}}{J^{5/3}}}\left(\lambda ^{2}-{\tfrac {J}{\lambda }}\right)}$ 

or

${\displaystyle D_{1}J^{8/3}-D_{1}J^{5/3}+{\tfrac {C_{1}}{3\lambda }}J-{\tfrac {C_{1}\lambda ^{2}}{3}}=0}$ 

The above equation can be solved numerically using a Newton–Raphson iterative root-finding procedure.

Under uniaxial extension, ${\displaystyle \lambda _{1}=\lambda \,}$  and ${\displaystyle \lambda _{2}=\lambda _{3}=1/{\sqrt {\lambda }}}$ . Therefore,

${\displaystyle \sigma _{11}-\sigma _{33}=2C_{1}\left(\lambda ^{2}-{\cfrac {1}{\lambda }}\right)~;~~\sigma _{22}-\sigma _{33}=0}$ 

Assuming no traction on the sides, ${\displaystyle \sigma _{22}=\sigma _{33}=0}$ , so we can write

${\displaystyle \sigma _{11}=2C_{1}\left(\lambda ^{2}-{\cfrac {1}{\lambda }}\right)=2C_{1}\left({\frac {3\varepsilon _{11}+3\varepsilon _{11}^{2}+\varepsilon _{11}^{3}}{1+\varepsilon _{11}}}\right)}$ 

where ${\displaystyle \varepsilon _{11}=\lambda -1}$  is the engineering strain. This equation is often written in alternative notation as

${\displaystyle T_{11}=2C_{1}\left(\alpha ^{2}-{\cfrac {1}{\alpha }}\right)}$ 

The equation above is for the true stress (ratio of the elongation force to deformed cross-section). For the engineering stress the equation is:

${\displaystyle \sigma _{11}^{\mathrm {eng} }=2C_{1}\left(\lambda -{\cfrac {1}{\lambda ^{2}}}\right)}$ 

For small deformations ${\displaystyle \varepsilon \ll 1}$  we will have:

${\displaystyle \sigma _{11}=6C_{1}\varepsilon =3\mu \varepsilon }$ 

Thus, the equivalent Young's modulus of a neo-Hookean solid in uniaxial extension is ${\displaystyle 3\mu }$ , which is in concordance with linear elasticity (${\displaystyle E=2\mu (1+\nu )}$  with ${\displaystyle \nu =0.5}$  for incompressibility).

In the case of equibiaxial extension

${\displaystyle \lambda _{1}=\lambda _{2}=\lambda ~;~~\lambda _{3}={\tfrac {J}{\lambda ^{2}}}~;~~I_{1}=2\lambda ^{2}+{\tfrac {J^{2}}{\lambda ^{4}}}}$ 

Therefore,

${\displaystyle {\begin{aligned}\sigma _{11}&=2C_{1}\left[{\cfrac {\lambda ^{2}}{J^{5/3}}}-{\cfrac {1}{3J}}\left(2\lambda ^{2}+{\cfrac {J^{2}}{\lambda ^{4}}}\right)\right]+2D_{1}(J-1)\\&=\sigma _{22}\\\sigma _{33}&=2C_{1}\left[{\cfrac {J^{1/3}}{\lambda ^{4}}}-{\cfrac {1}{3J}}\left(2\lambda ^{2}+{\cfrac {J^{2}}{\lambda ^{4}}}\right)\right]+2D_{1}(J-1)\end{aligned}}}$ 

The stress differences are

${\displaystyle \sigma _{11}-\sigma _{22}=0~;~~\sigma _{11}-\sigma _{33}={\cfrac {2C_{1}}{J^{5/3}}}\left(\lambda ^{2}-{\cfrac {J^{2}}{\lambda ^{4}}}\right)}$ 

If the material is in a state of plane stress then ${\displaystyle \sigma _{33}=0}$  and we have

${\displaystyle \sigma _{11}=\sigma _{22}={\cfrac {2C_{1}}{J^{5/3}}}\left(\lambda ^{2}-{\cfrac {J^{2}}{\lambda ^{4}}}\right)}$ 

We also have a relation between ${\displaystyle J}$  and ${\displaystyle \lambda }$ :

${\displaystyle 2C_{1}\left[{\cfrac {\lambda ^{2}}{J^{5/3}}}-{\cfrac {1}{3J}}\left(2\lambda ^{2}+{\cfrac {J^{2}}{\lambda ^{4}}}\right)\right]+2D_{1}(J-1)={\cfrac {2C_{1}}{J^{5/3}}}\left(\lambda ^{2}-{\cfrac {J^{2}}{\lambda ^{4}}}\right)}$ 

or,

${\displaystyle \left(2D_{1}-{\cfrac {C_{1}}{\lambda ^{4}}}\right)J^{2}+{\cfrac {3C_{1}}{\lambda ^{4}}}J^{4/3}-3D_{1}J-2C_{1}\lambda ^{2}=0}$ 

This equation can be solved for ${\displaystyle J}$  using Newton's method.

For an incompressible material ${\displaystyle J=1}$  and the differences between the principal Cauchy stresses take the form

${\displaystyle \sigma _{11}-\sigma _{22}=0~;~~\sigma _{11}-\sigma _{33}=2C_{1}\left(\lambda ^{2}-{\cfrac {1}{\lambda ^{4}}}\right)}$ 

Under plane stress conditions we have

${\displaystyle \sigma _{11}=2C_{1}\left(\lambda ^{2}-{\cfrac {1}{\lambda ^{4}}}\right)}$ 

For the case of pure dilation

${\displaystyle \lambda _{1}=\lambda _{2}=\lambda _{3}=\lambda ~:~~J=\lambda ^{3}~;~~I_{1}=3\lambda ^{2}}$ 

Therefore, the principal Cauchy stresses for a compressible neo-Hookean material are given by

${\displaystyle \sigma _{i}=2C_{1}\left({\cfrac {1}{\lambda ^{3}}}-{\cfrac {1}{\lambda }}\right)+2D_{1}(\lambda ^{3}-1)}$ 

If the material is incompressible then ${\displaystyle \lambda ^{3}=1}$  and the principal stresses can be arbitrary.

The figures below show that extremely high stresses are needed to achieve large triaxial extensions or compressions. Equivalently, relatively small triaxial stretch states can cause very high stresses to develop in a rubber-like material. The magnitude of the stress is quite sensitive to the bulk modulus but not to the shear modulus.

For the case of simple shear the deformation gradient in terms of components with respect to a reference basis is of the form^[2]

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

where ${\displaystyle \gamma }$  is the shear deformation. Therefore, the left Cauchy-Green deformation tensor is

${\displaystyle {\boldsymbol {B}}={\boldsymbol {F}}\cdot {\boldsymbol {F}}^{T}={\begin{bmatrix}1+\gamma ^{2}&\gamma &0\\\gamma &1&0\\0&0&1\end{bmatrix}}}$ 

In this case ${\displaystyle J=\det({\boldsymbol {F}})=1}$ . Hence, ${\displaystyle {\boldsymbol {\sigma }}=2C_{1}\operatorname {dev} ({\boldsymbol {B}})}$ . Now,

${\displaystyle \operatorname {dev} ({\boldsymbol {B}})={\boldsymbol {B}}-{\tfrac {1}{3}}\operatorname {tr} ({\boldsymbol {B}}){\boldsymbol {I}}={\boldsymbol {B}}-{\tfrac {1}{3}}(3+\gamma ^{2}){\boldsymbol {I}}={\begin{bmatrix}{\tfrac {2}{3}}\gamma ^{2}&\gamma &0\\\gamma &-{\tfrac {1}{3}}\gamma ^{2}&0\\0&0&-{\tfrac {1}{3}}\gamma ^{2}\end{bmatrix}}}$ 

Hence the Cauchy stress is given by

${\displaystyle {\boldsymbol {\sigma }}={\begin{bmatrix}{\tfrac {4C_{1}}{3}}\gamma ^{2}&2C_{1}\gamma &0\\2C_{1}\gamma &-{\tfrac {2C_{1}}{3}}\gamma ^{2}&0\\0&0&-{\tfrac {2C_{1}}{3}}\gamma ^{2}\end{bmatrix}}}$ 

Using the relation for the Cauchy stress for an incompressible neo-Hookean material we get

${\displaystyle {\boldsymbol {\sigma }}=-p~{\boldsymbol {I}}+2C_{1}{\boldsymbol {B}}={\begin{bmatrix}2C_{1}(1+\gamma ^{2})-p&2C_{1}\gamma &0\\2C_{1}\gamma &2C_{1}-p&0\\0&0&2C_{1}-p\end{bmatrix}}}$ 

Thus neo-Hookean solid shows linear dependence of shear stresses upon shear deformation and quadratic dependence of the normal stress difference on the shear deformation. The expressions for the Cauchy stress for a compressible and an incompressible neo-Hookean material in simple shear represent the same quantity and provide a means of determining the unknown pressure ${\displaystyle p}$ .

• Hyperelastic material
• Strain energy density function
• Mooney-Rivlin solid
• Finite strain theory
• Stress measures