Book contents
- Frontmatter
- Contents
- Preface
- List of abbreviations
- 1 Introduction
- 2 Elementary functional methods
- 3 Schwinger–Fradkin methods
- 4 Lasers and crossed lasers
- 5 Special variants of the Fradkin representation
- 6 Quantum chaos and vectorial interactions
- 7 Infrared approximations
- 8 Models of high-energy, non-Abelian scattering
- 9 Unitary ordered exponentials
- Index
6 - Quantum chaos and vectorial interactions
Published online by Cambridge University Press: 13 August 2009
- Frontmatter
- Contents
- Preface
- List of abbreviations
- 1 Introduction
- 2 Elementary functional methods
- 3 Schwinger–Fradkin methods
- 4 Lasers and crossed lasers
- 5 Special variants of the Fradkin representation
- 6 Quantum chaos and vectorial interactions
- 7 Infrared approximations
- 8 Models of high-energy, non-Abelian scattering
- 9 Unitary ordered exponentials
- Index
Summary
The possibility of quantum chaos for vectorial interactions is here described in some detail, along with its apparent suppression when the radiative corrections of quantum field theory (quantum fluctuations of the classical, “external” electromagnetic field) are introduced. Based on these quantum-mechanical ideas, an application is made to classical-chaotic systems, of perhaps the simplest form – a forced Duffing model, without damping – where it is found that the chaos is first suppressed and then (apparently) removed by introducing couplings to random and/or chaotic sources. This may be characterized as “quantum mechanics with ħ ∼ 1”, and suggests a brute-force method by which the chaos of a classical system may be at least diminished. A similar effect is noted for a different classical system that displays chaos – a pair of coupled oscillators – independently of any external forcing.
First-quantization chaos
The reader is now asked to return to the Gc[A] representations for vectorial interactions of the previous chapter; for simplicity, the arguments of this chapter are presented only for QED in a relativistic context, but have obvious generalizations to non-relativistic QED, and to relativistic QCD.
The map (5.31) defines the quantity Ωμ(s′), which is needed for the explicit solution of (5.33). It is the existence of such a map which carries with it the inescapable possibility of chaotic behavior, at least in the present context of vectorial interactions in potential theory. The analysis used here is given directly in terms of proper time τ, of which xμ(τ) is a function.
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- Information
- Green's Functions and Ordered Exponentials , pp. 93 - 106Publisher: Cambridge University PressPrint publication year: 2002