Ricci curvature
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In differential geometry, the Ricci curvature tensor, named after Gregorio Ricci-Curbastro, is (0,2)-valent tensor, obtained as a trace of the full curvature tensor. It can be thought of as a Laplacian of the Riemannian metric tensor in the case of Riemannian manifolds.
The Ricci tensor acting on vectors u and v, usually denoted by Ric(u,v), is defined as the trace of the endomorphism
- [w \mapsto R(w,v)u]
- [Ric = R_dx^i \otimes dx^j]
- [R_ = _].
- [Ric(u,v) = Ric(v,u)]
Ricci curvature can be also explained in terms of the sectional curvature in the following way: for a unit vector v, Ric(v,v) is sum of the sectional curvatures of all the planes spanned by the vector v and a vector from an orthonormal frame containing v (there are n−1 such planes).
One can think of Ricci curvature on a Riemannian manifold, as being an operator on the tangent bundle. That is, one can contract the Ricci tensor with the metric to obtain a (1,1)-valent tensor. In local coordinates,
- [}_j = g^R_]
- [Ric(u,v) = g(Ric(u), v)]
In dimensions 2 and 3 Ricci curvature describes completely the curvature tensor, but in higher dimensions Ricci curvature contains less information. For instance, Einstein manifolds do not have to have constant curvature in dimensions 4 and up.
An explicit expression for the Ricci tensor in terms of the Levi-Civita connection is given in the article on Christoffel symbols.
If you change the metric g by a conformal factor [e^] the Ricci-Curvature changes to
- [e^(Ric+(2-n)(Hess(f)-df\otimes df+\frac\|grad(f)\|^2g)-\Delta(f) g),]
Applications of the Ricci curvature tensor
The Ricci curvature can be used to define Chern classes of a manifold, which are topological invariants (so independent of the choice of metric).
Ricci curvature is also used in Ricci flow, where a metric is deformed in the direction of the Ricci curvature. On surfaces, the flow produces a metric of constant Gauss curvature and the uniformization theorem for surfaces follows. In dimension 3, it was recently used to give a complete classification of compact 3-manifolds.
Ricci curvature plays an important role in general relativity, where it is the key term in the Einstein field equations.
Global geometry/topology and Ricci curvature
Here is a short list of most basic results on manifolds with positive Ricci curvature.
- Myers theorem states that if Ricci curvature is bounded from below on a complete Riemannian manifold by [\left(n-1\right)k > 0 \,\!], then its diameter [\le \pi/\sqrt], and manifold has to have a finite fundamental group. If the diameter is equal to [\pi/\sqrt], then the manifold is isometric to a sphere of a constant curvature k.
- Bishop-Gromov inequality states that if Ricci curvature of a complete m-dimensional Riemannian manifold is ≥0 then the volume of a ball is smaller or equal to the volume of a ball of the same radius in Euclidean m-space. More over if [v_p(R)] denotes the volume of the ball with center p and radius [R] in the manifold and [V(R)=c_m R^m] denotes the volume of the ball of radius R in Euclidean m-space then function [v_p(R)/V(R)] is nonincreasing. (The last inequality can be generalized to arbitrary curvature bound and is the key point in the proof of Gromov's compactness theorem.)
- Splitting theorem states that if a complete Riemannian manifold with Ricc ≥ 0 has a straight line (i.e. a geodesic γ such that [d(\gamma(u),\gamma(v))=|u-v|] for all [v,u\in\mathbb]) then it is isometric to a product space [\mathbb\times L,] where [L] is a Riemannian manifold.
See also
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