Causal perturbation theory
From Wikipedia, the free encyclopedia
Causal perturbation theory is a mathematically rigorous approach to renormalization theory, which makes it possible to put the theoretical setup of perturbative quantum field theory on a sound mathematical basis. It goes back to a seminal work by Henri Epstein and Vladimir Jurko Glaser ("The role of locality in perturbation theory", published in Annales Poincare Phys. Theor. A19, p.211, 1973).
When developing quantum electrodynamics in the 1940s, Shin'ichiro Tomonaga, Julian Schwinger, Richard Feynman, and Freeman Dyson discovered that, in perturbative calculations, problems with divergent integrals abounded. The divergences appeared in calculations involving Feynman diagrams with closed loops of virtual particles. It is an important observation that in perturbative quantum field theory, time-ordered products of distributions arise in a natural way and may lead to ultraviolet divergences in the corresponding calculations. From the mathematical point of view, the problem of divergences is rooted in the fact that the theory of distributions is a purely linear theory, in the sense that the product of two distributions cannot consistently be defined (in general), as has been proved by Laurent Schwartz in the 1950's.
Epstein and Glaser solved this problem for a special class of distributions, which fulfill a causality condition, which itself is a basic requirement in axiomatic quantum field theory. In their original work, Epstein and Glaser studied only theories involving scalar (spinless) particles. In the meantime, the causal approach has been applied also to a wide range of gauge theories, which represent the most important quantum field theories in modern physics.
[edit] References
- Günter Scharf, Finite Quantum Electrodynamics: The Causal Approach, 2nd edition, Springer, New York (1995)
- Günter Scharf, Quantum Gauge Theories - A True Ghost Story,John Wiley & Sons, New York (2001)