Large-Order Perturbation Theory in Infrared-Unstable Superrenormalizable Field Theories

Abstract

We study the factorial divergences of Euclidean φ35, a problem with connections both to high-energy multiparticle scattering in d=4 and to d=3 (or high-temperature) gauge theory, which like φ35 is infrared-unstable and superrenormalizable. At large external momentum p (or small mass M) and large order N one might expect perturbative bare skeleton graphs to behave roughly like N!(ag2/p)N with a>0, so that no matter how large p is there is an N g2/p giving rise to strong perturbative amplitudes. The semi- classical Lipatov technique (which works only in the presence of a mass) is blind to this momentum dependence, so we proceed by direct summation of bare skeleton graphs. We find that the various limits of large N, large p, and small M do not commute, and that when N p2/M2 there is a Borel singularity associated with g2/M, not g2/p. This is described by the zero-momentum Lipatov technique, and we find the necessary soliton for φ35; the corresponding sphaleron-like solution for unbroken Yang-Mills theory has long been known. We also show that the massless theories have no classical solitons. We discuss non-perturbative effects based partly on known physical arguments concerning the cancellation by solitons of imaginary parts due to the pert- urbative Borel singularity, and partly on the dressing of bare skeleton graphs by dressed propagators showing non-perturbative mass generation, as happens in d=3 gauge theory.

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