中文

Classical and Quantum Physical Geometry

广义相对论与量子宇宙学 2007-05-23 v1 高能物理 - 理论

摘要

The task of quantizing gravity is compared with Einstein's relativization of gravity. The philosophical and physical foundations of general relativity are briefly reviewed. The Ehlers-Pirani-Schild scheme of operationally determining the geometry of space-time, using freely falling classical particle trajectories, is done using operations in an infinitesimal neighborhood around each point. The study of the free fall of a quantum wave suggests a quantum principle of equivalence. The principle of general covariance is clarified. The sign change of a Fermion field when rotated by 2π2\pi radians is used to argue for a quantum mechanical modification of space-time, which leads naturally to supersymmetry. A novel effect in quantum gravity due to the author is used to extend Einstein's hole argument to quantum gravity. This suggests a quantum principle of general covariance, according to which the fundamental laws of physics should be covariant under `quantum diffeomorphisms'. This heuristic principle implies that space-time points have no invariant meaning in quantum gravity.

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引用

@article{arxiv.gr-qc/9712015,
  title  = {Classical and Quantum Physical Geometry},
  author = {Jeeva S. Anandan},
  journal= {arXiv preprint arXiv:gr-qc/9712015},
  year   = {2007}
}

备注

31 pages, tex, 1 figure. Published in Potentiality, Entanglement and Passion-at-a-distance - Quantum Mechanical Studies for Abner Shimony, vol. 2, edited by R. S. Cohen, M. Horne and J. Stachel, (Kluwer, Dordrecht, Holland 1997), p. 31-52