Wave-packet collapse and the core quantum postulates: Discreteness of quantum jumps from unitarity, repeatability, and actionable information
Abstract
An unknown quantum state of a single system cannot be discovered, as a measured system is reprepared—it jumps into an eigenstate of the measured observable. This impossibility of finding the quantum state and other symptoms usually blamed on wave-packet collapse follow (as was recently demonstrated for pure states of measured systems) from unitarity (which does not, however, allow for a literal collapse) and from the repeatability of measurements: Continuous unitary evolution and repeatability suffice to establish the discreteness that underlies quantum jumps. Here we consider mixed states of a macroscopic, open system (such as an apparatus), and we allow its microscopic state to change when, e.g., measured by an observer, provided that its salient features remain unchanged and that observers regard macroscopic state of the pointer as representing the same record. We conclude that repeatably accessible states of macroscopic systems (such as the states of the apparatus pointer) must correspond to orthogonal subspaces in the Hilbert space. The symmetry breaking we exhibit defies the egalitarian quantum superposition principle and unitary symmetry of the Hilbert space, as it singles out preferred subspaces. We conclude that the resulting discreteness (which underlies quantum jumps) emerges from the continuity of the core quantum postulates plus repeatability also in macroscopic and open—but ultimately quantum—systems such as measuring devices accessed by observers, where (in contrast with pure states of microsystems) repeatability is paramount.
- Publication:
-
Physical Review A
- Pub Date:
- May 2013
- DOI:
- 10.1103/PhysRevA.87.052111
- arXiv:
- arXiv:1212.3245
- Bibcode:
- 2013PhRvA..87e2111Z
- Keywords:
-
- 03.65.Ta;
- 03.65.Yz;
- 03.67.-a;
- Foundations of quantum mechanics;
- measurement theory;
- Decoherence;
- open systems;
- quantum statistical methods;
- Quantum information;
- Quantum Physics;
- Condensed Matter - Statistical Mechanics;
- General Relativity and Quantum Cosmology;
- High Energy Physics - Theory
- E-Print:
- Changes in the presentation, figure added, etc