Gerhard Groessing
Published 2002-05-09, updated 2002-08-27Version 6
The Schroedinger- and Klein-Gordon equations are directly derived from classical Lagrangians. The only inputs are given by the discreteness of energy (E=hbar.w) and momentum (p=hbar.k), respectively, as well as the assumed existence of a space-pervading field of "zero-point energy" (E_0=hbar.w/2 per spatial dimension) associated to each particle of energy E. The latter leads to an additional kinetic energy term in the classical Lagrangian, which alone suffices to pass from classical to quantum mechanics. Moreover, Heisenberg's uncertainty relations are also derived within this framework, i.e., without referring to quantum mechanical or other complex-numbered functions.
Comments: 11 pages; improved and extended version thanks to very useful referee Reports
Journal: Substantially corrected version: quant-ph/0311109, Foundations of Physics Letters 17, 4 (2004) 343 - 362
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