Book contents
- Frontmatter
- Contents
- Foreword by Claude Cohen-Tannoudji
- Preface
- Table of units and physical constants
- 1 Introduction
- 2 The mathematics of quantum mechanics I: finite dimension
- 3 Polarization: photons and spin-1/2 particles
- 4 Postulates of quantum physics
- 5 Systems with a finite number of levels
- 6 Entangled states
- 7 Mathematics of quantum mechanics II: infinite dimension
- 8 Symmetries in quantum physics
- 9 Wave mechanics
- 10 Angular momentum
- 11 The harmonic oscillator
- 12 Elementary scattering theory
- 13 Identical particles
- 14 Atomic physics
- 15 Open quantum systems
- Appendix A The Wigner theorem and time reversal
- Appendix B Measurement and decoherence
- Appendix C The Wigner–Weisskopf method
- References
- Index
6 - Entangled states
Published online by Cambridge University Press: 05 January 2013
- Frontmatter
- Contents
- Foreword by Claude Cohen-Tannoudji
- Preface
- Table of units and physical constants
- 1 Introduction
- 2 The mathematics of quantum mechanics I: finite dimension
- 3 Polarization: photons and spin-1/2 particles
- 4 Postulates of quantum physics
- 5 Systems with a finite number of levels
- 6 Entangled states
- 7 Mathematics of quantum mechanics II: infinite dimension
- 8 Symmetries in quantum physics
- 9 Wave mechanics
- 10 Angular momentum
- 11 The harmonic oscillator
- 12 Elementary scattering theory
- 13 Identical particles
- 14 Atomic physics
- 15 Open quantum systems
- Appendix A The Wigner theorem and time reversal
- Appendix B Measurement and decoherence
- Appendix C The Wigner–Weisskopf method
- References
- Index
Summary
Up to now we have limited ourselves to states of a single particle. In the present chapter we shall introduce the description of two-particle states. Once this case is understood, it will be easy to generalize to any number of particles. States of two (or more) particles lead to very rich configurations called entangled states. A remarkable feature is that two entangled quantum particles, even at arbitrarily large spatial separations, continue to form a single entity and no classical probabilistic model is able to reproduce the correlation between particles. In the first section we shall present the essential mathematical formalism, that of the tensor product. This will permit us in Section 6.2 to describe quantum mixtures using the state operator formalism. Section 6.3 is devoted to the study of important physical consequences like the Bell inequalities and interference experiments involving entangled states, which will lead us to a deeper understanding of quantum physics. Finally, in the last section we shall briefly review applications to measurement theory and quantum information theory. The latter is undergoing rapid development at present and has applications to quantum computing, cryptography, and teleportation.
The tensor product of two vector spaces
Definition and properties of the tensor product
We wish to construct the space of states of two physical systems which we assume initially to be completely independent. Let ℌN1 and ℌM2 be the spaces of states of the two systems, of dimension N and M, respectively.
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- Information
- Quantum Physics , pp. 158 - 208Publisher: Cambridge University PressPrint publication year: 2006