In the mathematical theory of elasticity, Saint-Venant's compatibility condition defines the relationship between the strain

\varepsilon

and a displacement field

\ u

by :

\epsilon_ = \frac \left( \frac + \frac \right)

where

1\le i,j \le 3

. Barré de Saint-Venant derived the compatibility condition for an arbitrary symmetric second rank

tensor field In mathematics and physics, a tensor field assigns a tensor to each point of a mathematical space (typically a Euclidean space or manifold). Tensor fields are used in differential geometry, algebraic geometry, general relativity, in the analys ...

to be of this form, this has now been generalized to higher rank symmetric tensor fields on spaces of dimension

n\ge 2

Rank 2 tensor fields

For a symmetric rank 2 tensor field

F

in n-dimensional Euclidean space (

n \ge 2

) the

integrability condition In mathematics, certain systems of partial differential equations are usefully formulated, from the point of view of their underlying geometric and algebraic structure, in terms of a system of differential forms. The idea is to take advantage of t ...

takes the form of the vanishing of the Saint-Venant's tensor

W(F)

defined by :

W_ = \frac + 
\frac - \frac -\frac

The result that, on a

simply connected In topology, a topological space is called simply connected (or 1-connected, or 1-simply connected) if it is path-connected and every path between two points can be continuously transformed (intuitively for embedded spaces, staying within the spa ...

domain W=0 implies that strain is the symmetric derivative of some vector field, was first described by Barré de Saint-Venant in 1864 and proved rigorously by Beltrami in 1886. For non-simply connected domains there are finite dimensional spaces of symmetric tensors with vanishing Saint-Venant's tensor that are not the symmetric derivative of a vector field. The situation is analogous to

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The Saint-Venant tensor

W

is closely related to the

Riemann curvature tensor In the mathematical field of differential geometry, the Riemann curvature tensor or Riemann–Christoffel tensor (after Bernhard Riemann and Elwin Bruno Christoffel) is the most common way used to express the curvature of Riemannian manifolds ...

R_

. Indeed the first variation

R

about the Euclidean metric with a perturbation in the metric

F

is precisely

W

. Consequently the number of independent components of

W

is the same as

R

D. V. Georgiyecskii and B. Ye. Pobedrya,The number of independent compatibility equations in the mechanics of deformable solids, Journal of Applied Mathematicsand Mechanics,68 (2004)941-946 specifically

\frac

for dimension n. Specifically for

n=2

W

has only one independent component where as for

n=3

there are six. In its simplest form of course the components of

F

must be assumed twice continuously differentiable, but more recent workC Amrouche, PG Ciarlet, L Gratie, S Kesavan, On Saint Venant's compatibility conditions and Poincaré's lemma, C. R. Acad. Sci. Paris, Ser. I, 342 (2006), 887-891. proves the result in a much more general case. The relation between Saint-Venant's compatibility condition and

Poincaré's lemma In mathematics, especially vector calculus and differential topology, a closed form is a differential form ''α'' whose exterior derivative is zero (), and an exact form is a differential form, ''α'', that is the exterior derivative of another dif ...

can be understood more clearly using a reduced form of

W

the Kröner tensor :

K_ = \epsilon_\epsilon_F_

where

\epsilon

is the

permutation symbol In mathematics, particularly in linear algebra, tensor analysis, and differential geometry, the Levi-Civita symbol or Levi-Civita epsilon represents a collection of numbers; defined from the sign of a permutation of the natural numbers , for so ...

. For

n=3

K

is a symmetric rank 2 tensor field. The vanishing of

K

is equivalent to the vanishing of

W

and this also shows that there are six independent components for the important case of three dimensions. While this still involves two derivatives rather than the one in the Poincaré lemma, it is possible to reduce to a problem involving first derivatives by introducing more variables and it has been shown that the resulting 'elasticity complex' is equivalent to the

de Rham complex In mathematics Mathematics is an area of knowledge that includes the topics of numbers, formulas and related structures, shapes and the spaces in which they are contained, and quantities and their changes. These topics are represented in m ...

. In differential geometry the symmetrized derivative of a vector field appears also as the

Lie derivative In differential geometry, the Lie derivative ( ), named after Sophus Lie by Władysław Ślebodziński, evaluates the change of a tensor field (including scalar functions, vector fields and one-forms), along the flow defined by another vecto ...

of the metric tensor ''g'' with respect to the vector field. :

T_=(\mathcal L_U g)_ = U_+U_

where indices following a semicolon indicate covariant differentiation. The vanishing of

W(T)

is thus the integrability condition for local existence of

U

in the Euclidean case. As noted above this coincides with the vanishing of the linearization of the Riemann curvature tensor about the Euclidean metric.

Generalization to higher rank tensors

Saint-Venant's compatibility condition can be thought of as an analogue, for symmetric tensor fields, of

for skew-symmetric tensor fields (

differential form In mathematics, differential forms provide a unified approach to define integrands over curves, surfaces, solids, and higher-dimensional manifolds. The modern notion of differential forms was pioneered by Élie Cartan. It has many application ...

s). The result can be generalized to higher rank

symmetric tensor In mathematics, a symmetric tensor is a tensor that is invariant under a permutation of its vector arguments: :T(v_1,v_2,\ldots,v_r) = T(v_,v_,\ldots,v_) for every permutation ''σ'' of the symbols Alternatively, a symmetric tensor of ord ...

fields. V.A. Sharafutdinov, Integral Geometry of Tensor Fields, VSP 1994,. Chapter
on-line version
/ref> Let F be a symmetric rank-k tensor field on an open set in n-dimensional

Euclidean space Euclidean space is the fundamental space of geometry, intended to represent physical space. Originally, that is, in Euclid's ''Elements'', it was the three-dimensional space of Euclidean geometry, but in modern mathematics there are Euclidean sp ...

, then the symmetric derivative is the rank k+1 tensor field defined by :

(dF)_ = F_

where we use the classical notation that indices following a comma indicate differentiation and groups of indices enclosed in brackets indicate symmetrization over those indices. The Saint-Venant tensor

W

of a symmetric rank-k tensor field

T

is defined by :

W_=V_

with :

V_ = \sum\limits_^ (-1)^p   T_{i_1..i_{k-p}j_1...j_p,j_{p+1}...j_k i_{k-p+1}...i_k }

On a

domain in Euclidean space

W=0

implies that

T = dF

for some rank k-1 symmetric tensor field

F

Rank 2 tensor fields

Generalization to higher rank tensors

References

See also