Book contents
- Frontmatter
- Contents
- Preface
- Copyright acknowledgements
- 1 Wave-particle duality
- 2 Cavity quantum electrodynamics
- 3 Quantum nondemolition measurements
- 4 Topological phases
- 5 Macroscopic quantum coherence
- 6 The quantum Zeno paradox
- 7 Testing collapse
- 8 Macroscopic quantum jumps
- 9 Nonlocality
- 10 Tunneling times
- References
- Author index
- Subject index
7 - Testing collapse
Published online by Cambridge University Press: 27 October 2009
- Frontmatter
- Contents
- Preface
- Copyright acknowledgements
- 1 Wave-particle duality
- 2 Cavity quantum electrodynamics
- 3 Quantum nondemolition measurements
- 4 Topological phases
- 5 Macroscopic quantum coherence
- 6 The quantum Zeno paradox
- 7 Testing collapse
- 8 Macroscopic quantum jumps
- 9 Nonlocality
- 10 Tunneling times
- References
- Author index
- Subject index
Summary
Introduction
In spite of its wonderful agreement with every experiment performed so far, standard quantum theory (SQT) fails to describe events and to define the circumstances under which such events occur [171]. It is the linearity of Schrödinger evolution that lies, as we have seen, at the root of the problem. A state vector always evolves to become a linear superposition of the states corresponding to several possible outcomes of a measurement, and it is only when an experiment is actually done that one of these possible outcomes is realized at a particular instant. Thereupon the state has to be changed to the one corresponding to the particular outcome in order to follow its subsequent evolution. This additional information is not contained in the theory and has to be obtained from outside. This means that the theory is unable to predict when an event will occur. All it can predict is that if an event occurs, the possible outcomes and their probabilities are such and such. Since events do occur in every experiment, there is something missing from the theory.
Since a state vector can be written as the linear sum of a complete set of basis states and these basis states can be chosen in a number of ways, each of which corresponds to a different set of outcomes, the theory also fails to tell us how to choose the preferred basis.
- Type
- Chapter
- Information
- Testing Quantum Mechanics on New Ground , pp. 116 - 131Publisher: Cambridge University PressPrint publication year: 1999