Large Orders for Self-Avoiding Membranes
Abstract
We derive the large order behavior of the perturbative expansion for the continuous model of tethered self-avoiding membranes. It is controlled by a classical configuration for an effective potential in bulk space, which is the analog of the Lipatov instanton, solution of a highly non-local equation. The n-th order is shown to have factorial growth as (-cst)^n (n!)^(1-epsilon/D), where D is the `internal' dimension of the membrane and epsilon the engineering dimension of the coupling constant for self-avoidance. The instanton is calculated within a variational approximation, which is shown to become exact in the limit of large dimension d of bulk space. This is the starting point of a systematic 1/d expansion. As a consequence, the epsilon-expansion of self-avoiding membranes has a factorial growth, like the epsilon-expansion of polymers and standard critical phenomena, suggesting Borel summability. Consequences for the applicability of the 2-loop calculations are examined.
Keywords
Cite
@article{arxiv.cond-mat/9807160,
title = {Large Orders for Self-Avoiding Membranes},
author = {Francois David and Kay Joerg Wiese},
journal= {arXiv preprint arXiv:cond-mat/9807160},
year = {2009}
}
Comments
40 pages Latex, 32 eps-files included in the text