Hofer's L∞-geometry: energy and stability of Hamiltonian flows, part II

Abstract

In this paper we first show that the necessary condition introduced in our previous paper is also a sufficient condition for a path to be a geodesic in the group c(M) of compactly supported Hamiltonian symplectomorphisms. This applies with no restriction on M. We then discuss conditions which guarantee that such a path minimizes the Hofer length. Our argument relies on a general geometric construction (the gluing of monodromies) and on an extension of Gromov's non-squeezing theorem both to more general manifolds and to more general capacities. The manifolds we consider are quasi-cylinders, that is spaces homeomorphic to M × D2 which are symplectically ruled over D2. When we work with the usual capacity (derived from embedded balls), we can prove the existence of paths which minimize the length among all homotopic paths, provided that M is semi-monotone. (This restriction occurs because of the well-known difficulty with the theory of J-holomorphic curves in arbitrary M.) However, we can only prove the existence of length-minimizing paths (i.e. paths which minimize length amongst all paths, not only the homotopic ones) under even more restrictive conditions on M, for example when M is exact and convex or of dimension 2. The new difficulty is caused by the possibility that there are non-trivial and very short loops in c(M). When such length-minimizing paths do exist, we can extend the Bialy--Polterovich calculation of the Hofer norm on a neighbourhood of the identity (C1-flatness).

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