Complete Hamiltonian Description of Wave-Like Features in Classical and Quantum Physics

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Foundations of Physics 39 (3):256-272 (2009)
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Abstract

The analysis of the Helmholtz equation is shown to lead to an exact Hamiltonian system describing in terms of ray trajectories, for a stationary refractive medium, a very wide family of wave-like phenomena (including diffraction and interference) going much beyond the limits of the geometrical optics (“eikonal”) approximation, which is contained as a simple limiting case. Due to the fact, moreover, that the time independent Schrödinger equation is itself a Helmholtz-like equation, the same mathematics holding for a classical optical beam turns out to apply to a quantum particle beam moving in a stationary force field, and leads to a system of Hamiltonian equations providing exact and deterministic particle trajectories and dynamical laws, and containing the laws of Classical Mechanics in the eikonal limit

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10.1007/s10701-009-9280-2

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Wholeness and the implicate order.David Bohm - 1980 - New York: Routledge.
Wholeness and the Implicate Order.David Bohm - 1980 - New York: Routledge.

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