Nonpositively curved implies conjugate-free: Difference between revisions

Latest revision as of 19:50, 18 May 2008

Statement

Verbal statement

If the sectional curvature of a Riemannian manifold is everywhere nonpositive, then the Riemannian manifold is conjugate-free, viz it does not contain a pair of conjugate points.

Proof

Let $M$ be the Riemannian manifold, $γ$ a geodesic in $M$ and $J$ a Jacobi field about $γ$ that vanishes at the endpoints. We must show that $J$ is everywhere zero.

Consider the Jacobi equation:

$\frac{D^{2} J}{d t^{2}} + R (J, V) V = 0$

Taking the inner product of both these with $J$ , the second term becomes the sectional curvature of the tangent plane spanned by $J$ and $V$ , which is negative. Hence we conclude that:

$< \frac{D^{2} J}{d t^{2}}, J > \geq 0$

This tells us that $< \frac{D J}{d t}, J >$ is nondecreasing, and hence, that $< J, J >$ is nondecreasing. Thus $J$ cannot be zero at both endpoints unless it is identically zero.

Application

This observation is crucial to the proof of the Cartan-Hadamard theorem.

@@ Line 3: / Line 3: @@
 ===Verbal statement===
-If the [[sectional curvature]] of a [[Riemannian manifold]] is everywhere nonpositive, then the Riemannian manifold os [[conjugate-free Riemannian manifold|conjugate-free]], viz it does not contain a pair of conjugate points.
+If the [[sectional curvature]] of a [[Riemannian manifold]] is everywhere nonpositive, then the Riemannian manifold is [[conjugate-free Riemannian manifold|conjugate-free]], viz it does not contain a pair of conjugate points.
 ==Proof==
@@ Line 13: / Line 13: @@
 <math>\frac{D^2J}{dt^2} + R(J,V)V = 0</math>
-Taking the inner product of both these with <math>J</math>, the second term becomes the [[sectional curvature]] of the tangent plane spanned by <math>J</math> and <math>V</math>, which is nonpositive. Hence we conclude that:
+Taking the inner product of both these with <math>J</math>, the second term becomes the [[sectional curvature]] of the tangent plane spanned by <math>J</math> and <math>V</math>, which is negative. Hence we conclude that:
 <math><\frac{D^2J}{dt^2},J> \ge 0</math>
-This tells us that
+This tells us that <math><\frac{DJ}{dt},J></math> is nondecreasing, and hence, that <math><J,J></math> is nondecreasing. Thus <math>J</math> cannot be zero at both endpoints unless it is identically zero.
+==Application==
+This observation is crucial to the proof of the [[Cartan-Hadamard theorem]].