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Transactions of the American Mathematical Society

Published by the American Mathematical Society since 1900, Transactions of the American Mathematical Society is devoted to longer research articles in all areas of pure and applied mathematics.

ISSN 1088-6850 (online) ISSN 0002-9947 (print)

The 2020 MCQ for Transactions of the American Mathematical Society is 1.48.

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Are Hamiltonian flows geodesic flows?
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by Christopher McCord, Kenneth R. Meyer and Daniel Offin PDF
Trans. Amer. Math. Soc. 355 (2003), 1237-1250 Request permission

Abstract:

When a Hamiltonian system has a “Kinetic + Potential” structure, the resulting flow is locally a geodesic flow. But there may be singularities of the geodesic structure; so the local structure does not always imply that the flow is globally a geodesic flow. In order for a flow to be a geodesic flow, the underlying manifold must have the structure of a unit tangent bundle. We develop homological conditions for a manifold to have such a structure.

We apply these criteria to several classical examples: a particle in a potential well, the double spherical pendulum, the Kovalevskaya top, and the $N$-body problem. We show that the flow of the reduced planar $N$-body problem and the reduced spatial 3-body are never geodesic flows except when the angular momentum is zero and the energy is positive.

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Additional Information
  • Christopher McCord
  • Affiliation: University of Cincinnati, Cincinnati, Ohio 45221-0025
  • Email: CHRIS.MCCORD@UC.EDU
  • Kenneth R. Meyer
  • Affiliation: University of Cincinnati, Cincinnati, Ohio 45221-0025
  • Email: KEN.MEYER@UC.EDU
  • Daniel Offin
  • Affiliation: Queen’s University, Kingston, Ontario K7L 4V1, Canada
  • Email: OFFIND@MAST.QUEENSU.CA
  • Received by editor(s): January 2, 2002
  • Received by editor(s) in revised form: May 10, 2002
  • Published electronically: October 17, 2002
  • Additional Notes: This research was partially supported by grants from the Taft Foundation, the NSF and the NSERC
  • © Copyright 2002 American Mathematical Society
  • Journal: Trans. Amer. Math. Soc. 355 (2003), 1237-1250
  • MSC (2000): Primary 37N05, 34C27, 54H20
  • DOI: https://doi.org/10.1090/S0002-9947-02-03167-7
  • MathSciNet review: 1938755