How many geodesics join two points on a contact sub-Riemannian manifold?

Abstract

We investigate the number of geodesics between two points p and q on a contact sub-Riemannian manifold M. We show that the count of geodesics on M is controlled by the count on its nilpotent approximation at p (a contact Carnot group). For contact Carnot groups we make the count explicit in exponential coordinates (x,z) ∈ R2n × R centered at p. In this case we prove that for the generic q the number of geodesics (q) between p and q=(x,z) satisfies: \[ C1|z|\|x\|2 + R1 ≤ (q) ≤ C2|z|\|x\|2 + R2\] for some constants C1,C2 and R1,R2. We recover exact values for Heisenberg groups, where C1=C2 = 8π. Removing the genericity condition for q, geodesics might appear in families and we prove a similar statement for their topology. We study these families, and in particular we focus on the unexpected appearance of isometrically non-equivalent geodesics: families on which the action of isometries is not transitive. We apply the previous study to contact sub-Riemannian manifolds: we prove that for any given point p ∈ M there is a sequence of points pn such that pn p and that the number of geodesics between p and pn grows unbounded (moreover these geodesics have the property of being contained in a small neighborhood of p).