Codazzi tensor explained

In the mathematical field of differential geometry, a Codazzi tensor (named after Delfino Codazzi) is a symmetric 2-tensor whose covariant derivative is also symmetric. Such tensors arise naturally in the study of Riemannian manifolds with harmonic curvature or harmonic Weyl tensor. In fact, existence of Codazzi tensors impose strict conditions on the curvature tensor of the manifold. Also, the second fundamental form of an immersed hypersurface in a space form (relative to a local choice of normal field) is a Codazzi tensor.

Definition

Let

(M,g)

be a n-dimensional Riemannian manifold for

n\geq3

, let

be a symmetric 2-tensor field, and let

\nabla

be the Levi-Civita connection. We say that the tensor

is a Codazzi tensor if

(\nabla_XT)(Y,Z)=(\nabla_YT)(X,Z)

for all

X,Y,Z\inT_pM.

Examples

Any parallel -tensor field is, trivially, Codazzi.
Let

(N,\overline{g})

be a space form, let

be a smooth manifold with

1+\dimM=\dimN,

and let

F:M\toN

be an immersion. If there is a global choice of unit normal vector field, then relative to this choice, the second fundamental form is a Codazzi tensor on

This is an immediate consequence of the Gauss-Codazzi equations.

(M,g)

be a space form with constant curvature

\kappa.

Given any function

the tensor

\operatorname{Hess}^gf+\kappafg

is Codazzi. This is a consequence of the commutation formula for covariant differentiation.

(M,g)

be a two-dimensional Riemannian manifold, and let

be the Gaussian curvature. Then

2\operatorname{Hess}^gK+K^2g

is a Codazzi tensor. This is a consequence of the commutation formula for covariant differentiation.

Let Rm denote the Riemann curvature tensor. Then (" has harmonic curvature tensor") if and only if the Ricci tensor is a Codazzi tensor. This is an immediate consequence of the contracted Bianchi identity.
Let denote the Weyl curvature tensor. Then

\operatorname{div}W=0

(" has harmonic Weyl tensor") if and only if the "Schouten tensor"

\operatorname{Ric}-	1
	2n-2

is a Codazzi tensor. This is an immediate consequence of the definition of the Weyl tensor and the contracted Bianchi identity.

Rigidity

Matsushima and Tanno showed that, on a Kähler manifold, any Codazzi tensor which is hermitian is parallel. Berger showed that, on a compact manifold of nonnegative sectional curvature, any Codazzi tensor with constant must be parallel. Furthermore, on a compact manifold of nonnegative sectional curvature, if the sectional curvature is strictly positive at least one point, then every symmetric parallel 2-tensor is a constant multiple of the metric.

References

Arthur Besse, Einstein Manifolds, Springer (1987).

Codazzi tensor explained

Definition

Examples

Rigidity

See also

References