English

Vector Fields, Flows and Lie Groups of Diffeomorphisms

High Energy Physics - Theory 2009-01-07 v1

Abstract

The freedom in choosing finite renormalizations in quantum field theories (QFT) is characterized by a set of parameters {ci},i=1...,n>...\{c_i \}, i = 1 ..., n >..., which specify the renormalization prescriptions used for the calculation of physical quantities. For the sake of simplicity, the case of a single cc is selected and chosen mass-independent if masslessness is not realized, this with the aim of expressing the effect of an infinitesimal change in cc on the computed observables. This change is found to be expressible in terms of an equation involving a vector field VV on the action's space MM (coordinates x). This equation is often referred to as ``evolution equation'' in physics. This vector field generates a one-parameter (here cc) group of diffeomorphisms on MM. Its flow σc(x)\sigma_c (x) can indeed be shown to satisfy the functional equation σc+t(x)=σc(σt(x))σcσt \sigma_{c+t} (x) = \sigma_c (\sigma_t (x)) \equiv \sigma_c \circ \sigma_t σ0(x)=x,\sigma_0 (x) = x, so that the very appearance of VV in the evolution equation implies at once the Gell-Mann-Low functional equation. The latter appears therefore as a trivial consequence of the existence of a vector field on the action's space of renormalized QFT.

Keywords

Cite

@article{arxiv.hep-th/9912131,
  title  = {Vector Fields, Flows and Lie Groups of Diffeomorphisms},
  author = {A. Peterman},
  journal= {arXiv preprint arXiv:hep-th/9912131},
  year   = {2009}
}

Comments

(8 pages, latex)