Home

hyperelastic

Hyperelasticity is a constitutive framework in continuum mechanics used to model the nonlinear elastic response of solids undergoing large deformations. In a hyperelastic material, the stress state is derived from a strain energy density function W that depends on the deformation gradient F, or equivalently on the right Cauchy-Green tensor C = F^T F. The work done by stresses during deformation is recoverable, and the material is considered elastic and path-independent under isothermal, quasi-static conditions.

The second Piola-Kirchhoff stress S is given by S = 2 ∂W/∂C, and the Cauchy stress sigma is

Common models of hyperelasticity include Neo-Hookean, which is the simplest and based on W proportional to

Applications of hyperelastic models are widespread in engineering and biomechanics, particularly for rubber-like polymers, elastomers, and

Limitations include the assumption of rate-independent, purely elastic behavior, which excludes time-dependent phenomena such as viscoelasticity,

obtained
from
sigma
=
(1/J)
F
S
F^T,
with
J
=
det
F.
For
incompressible
hyperelastic
materials,
the
constraint
J
=
1
introduces
a
Lagrange
multiplier
p,
appearing
as
an
isotropic
pressure
term
in
the
Cauchy
stress.
I1
−
3;
Mooney-Rivlin,
which
depends
on
the
invariants
I1
and
I2;
Ogden,
which
uses
principal
stretches
with
power-law
forms;
as
well
as
Gent
and
Arruda-Boyce,
which
reflect
network
behavior.
These
models
provide
closed-form
expressions
for
W
and
permit
straightforward
derivation
of
stresses
under
finite
deformations.
soft
tissues
such
as
arteries
and
skin.
They
are
routinely
used
in
finite
element
analysis
to
predict
large-strain
behavior
and
to
simulate
material
response
under
complex
loading.
hysteresis,
and
damage.
In
practice,
hyperelastic
models
are
often
complemented
by
viscoelastic
or
damage
terms,
and
require
careful
calibration
to
experimental
data.