In the calculus of variations, the notion of polyconvexity is a generalization of the notion of convexity for functions defined on spaces of matrices. The notion of polyconvexity was introduced by John M. Ball as a sufficient conditions for proving the existence of energy minimizers in nonlinear elasticity theory.[1] It is satisfied by a large class of hyperelastic stored energy densities, such as Mooney-Rivlin and Ogden materials. The notion of polyconvexity is related to the notions of convexity, quasiconvexity and rank-one convexity through the following diagram:[2]

Motivation

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Let   be an open bounded domain,   and   denote the Sobolev space of mappings from   to  . A typical problem in the calculus of variations is to minimize a functional,   of the form

 ,

where the energy density function,   satisfies  -growth, i.e.,   for some   and  . It is well-known from a theorem of Morrey and Acerbi-Fusco that a necessary and sufficient condition for   to weakly lower-semicontinuous on   is that   is quasiconvex for almost every  . With coercivity assumptions on   and boundary conditions on  , this leads to the existence of minimizers for   on  .[3] However, in many applications, the assumption of  -growth on the energy density is often too restrictive. In the context of elasticity, this is because the energy is required to grow unboundedly to   as local measures of volume approach zero. This led Ball to define the more restrictive notion of polyconvexity to prove the existence of energy minimizers in nonlinear elasticity.

Definition

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A function   is said to be polyconvex[4] if there exists a convex function   such that

 

where   is such that

 

Here,   stands for the matrix of all   minors of the matrix  ,   and

 

where  .

When  ,   and when  ,  , where   denotes the cofactor matrix of  .

In the above definitions, the range of   can also be extended to  .

Properties

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  • If   takes only finite values, then polyconvexity implies quasiconvexity and thus leads to the weak lower semicontinuity of the corresponding integral functional on a Sobolev space.
  • If   or  , then polyconvexity reduces to convexity.
  • Polyconvex functions with subquadratic growth must be convex, i.e., if there exists   and   such that
  for every  , then   is convex.

Examples

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  • Every convex function is polyconvex.
  • For the case  , the determinant function is polyconvex, but not convex. In particular, the following type of function that commonly appears in nonlinear elasticity is polyconvex but not convex:
 

References

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  1. ^ Ball, John M. (1976). "Convexity conditions and existence theorems in nonlinear elasticity" (PDF). Archive for Rational Mechanics and Analysis. 63 (4). Springer: 337–403. doi:10.1007/BF00279992.
  2. ^ Dacorogna, Bernard (2008). Direct Methods in the Calculus of Variations. Applied mathematical sciences. Vol. 78 (2nd ed.). Springer Science+Business Media, LLC. p. 156. doi:10.1007/978-0-387-55249-1. ISBN 978-0-387-35779-9.
  3. ^ Rindler, Filip (2018). Calculus of Variations. Universitext. Springer International Publishing AG. p. 124-125. doi:10.1007/978-3-319-77637-8. ISBN 978-3-319-77636-1.
  4. ^ Dacorogna, Bernard (2008). Direct Methods in the Calculus of Variations. Applied mathematical sciences. Vol. 78 (2nd ed.). Springer Science+Business Media, LLC. p. 157. doi:10.1007/978-0-387-55249-1. ISBN 978-0-387-35779-9.