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
3 - Polarization: photons and spin-1/2 particles
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
In this chapter we build up the basic concepts of quantum mechanics using two simple examples, following a heuristic approach which is more inductive than deductive. We start with a familiar phenomenon, that of the polarization of light, which will allow us to introduce the necessary mathematical formalism. We show that the description of polarization leads naturally to the need for a two-dimensional complex vector space, and we establish the correspondence between a polarization state and a vector in this space, referred to as the space of polarization states. We then move on to the quantum description of photon polarization and illustrate the construction of probability amplitudes as scalar products in this space. The second example will be that of spin 1/2, where the space of states is again two-dimensional. We construct the most general states of spin 1/2 using rotational invariance. Finally, we introduce dynamics, which allows us to follow the time evolution of a state vector.
The analogy with the polarization of light will serve as a guide to constructing the quantum theory of photon polarization, but no such classical analog is available for constructing the quantum theory for spin 1/2. In this case the quantum theory will be constructed without reference to any classical theory, using an assumption about the dimension of the space of states and symmetry principles.
The polarization of light and photon polarization
The polarization of an electromagnetic wave
The polarization of light or, more generally, of an electromagnetic wave, is a familiar phenomenon related to the vector nature of the electromagnetic field. Let us consider a plane wave of monochromatic light of frequency ω propagating in the positive z direction.
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- Quantum Physics , pp. 61 - 95Publisher: Cambridge University PressPrint publication year: 2006