Detlef Dürr, Sheldon Goldstein, Nino Zanghí
Published 2003-08-06Version 1
The quantum formalism is a ``measurement'' formalism--a phenomenological formalism describing certain macroscopic regularities. We argue that it can be regarded, and best be understood, as arising from Bohmian mechanics, which is what emerges from Schr\"odinger's equation for a system of particles when we merely insist that ``particles'' means particles. While distinctly non-Newtonian, Bohmian mechanics is a fully deterministic theory of particles in motion, a motion choreographed by the wave function. We find that a Bohmian universe, though deterministic, evolves in such a manner that an {\it appearance} of randomness emerges, precisely as described by the quantum formalism and given, for example, by ``$\rho=|\psis|^2$.'' A crucial ingredient in our analysis of the origin of this randomness is the notion of the effective wave function of a subsystem, a notion of interest in its own right and of relevance to any discussion of quantum theory. When the quantum formalism is regarded as arising in this way, the paradoxes and perplexities so often associated with (nonrelativistic) quantum theory simply evaporate.
Comments: 75 pages. This paper was published a long time ago, but was never archived. We do so now because it is basic for our recent article quant-ph/0308038, which can in fact be regarded as an appendix of the earlier one
Journal: Journ. of Statistical Phys. 67, 843-907 (1992)
On the Uniqueness of Quantum Equilibrium in Bohmian Mechanics
On the Common Structure of Bohmian Mechanics and the Ghirardi-Rimini-Weber Theory
Position Measurements and the Empirical Status of Particles in Bohmian Mechanics
