Cluster Convergence Theorem
Abstract
A power-counting theorem is presented, that is designed to play an analogous role, in the proof of a BPHZ convergence theorem, in Euclidean position space, to the role played by Weinberg's power-counting theorem, in Zimmermann's proof of the BPHZ convergence theorem, in momentum space. If denotes a position space configuration, of the vertices, of a Feynman diagram, and is a real number, such that , a -cluster, of , is a nonempty subset, , of the vertices of the diagram, such that the maximum distance, between any two vertices, in , is less than , times the minimum distance, from any vertex, in , to any vertex, not in . The set of all the -clusters, of , has similar combinatoric properties to a forest, and the configuration space, of the vertices, is cut up into a finite number of sectors, classified by the set of all their -clusters. It is proved that if, for each such sector, the integrand can be bounded by an expression, that satisfies a certain power-counting requirement, for each -cluster, then the integral, over the position, of any one vertex, is absolutely convergent, and the result can be bounded by the sum of a finite number of expressions, of the same type, each of which satisfies the corresponding power-counting requirements.
Cite
@article{arxiv.hep-th/0509033,
title = {Cluster Convergence Theorem},
author = {Chris Austin},
journal= {arXiv preprint arXiv:hep-th/0509033},
year = {2007}
}
Comments
LaTeX2e transcription of 1988 paper, with references added. 42 pages. Needs amsfonts. For an application of the theorem to a BPHZ convergence proof, in Euclidean position space, without exponentiating the propagators, see http://web.ukonline.co.uk/chrisaustin/