Riemannian submersion

In differential geometry, a branch of mathematics, a Riemannian submersion is a submersion from one Riemannian manifold to another that respects the metrics, meaning that it is an orthogonal projection on tangent spaces.

Formal definition[edit]

Let (M, g) and (N, h) be two Riemannian manifolds and $f:M\to N$ a (surjective) submersion, i.e., a fibered manifold. The horizontal distribution $K:=\mathrm {ker} (df)^{\perp }$ is a sub-bundle of the tangent bundle of $TM$ which depends both on the projection $f$ and on the metric $g$ .

Then, f is called a Riemannian submersion if and only if, for all $x\in M$ , the vector space isomorphism $(df)_{x}:K_{x}\rightarrow T_{f(x)}N$ is isometric, i.e., length-preserving.^[1]

Examples[edit]

An example of a Riemannian submersion arises when a Lie group $G$ acts isometrically, freely and properly on a Riemannian manifold $(M,g)$ . The projection $\pi :M\rightarrow N$ to the quotient space $N=M/G$ equipped with the quotient metric is a Riemannian submersion. For example, component-wise multiplication on $S^{3}\subset \mathbb {C} ^{2}$ by the group of unit complex numbers yields the Hopf fibration.

Properties[edit]

The sectional curvature of the target space of a Riemannian submersion can be calculated from the curvature of the total space by O'Neill's formula, named for Barrett O'Neill:

K_{N}(X,Y)=K_{M}({\tilde {X}},{\tilde {Y}})+{\tfrac {3}{4}}|[{\tilde {X}},{\tilde {Y}}]^{V}|^{2}

where $X,Y$ are orthonormal vector fields on $N$ , ${\tilde {X}},{\tilde {Y}}$ their horizontal lifts to $M$ , $[*,*]$ is the Lie bracket of vector fields and $Z^{V}$ is the projection of the vector field $Z$ to the vertical distribution.

In particular the lower bound for the sectional curvature of $N$ is at least as big as the lower bound for the sectional curvature of $M$ .

Generalizations and variations[edit]

Notes[edit]

^ Gilkey, Peter B.; Leahy, John V.; Park, Jeonghyeong (1998), Spinors, Spectral Geometry, and Riemannian Submersions, Global Analysis Research Center, Seoul National University, pp. 4–5

References[edit]

Gilkey, Peter B.; Leahy, John V.; Park, Jeonghyeong (1998), Spinors, Spectral Geometry, and Riemannian Submersions, Global Analysis Research Center, Seoul National University.
Barrett O'Neill. The fundamental equations of a submersion. Michigan Math. J. 13 (1966), 459–469. doi:10.1307/mmj/1028999604

This differential geometry-related article is a stub. You can help Wikipedia by expanding it.

[1] Gilkey, Peter B.; Leahy, John V.; Park, Jeonghyeong (1998), Spinors, Spectral Geometry, and Riemannian Submersions, Global Analysis Research Center, Seoul National University, pp. 4–5

[1]