English

Field Theories for Loop-Erased Random Walks

Statistical Mechanics 2019-11-18 v3 High Energy Physics - Theory Mathematical Physics math.MP

Abstract

Self-avoiding walks (SAWs) and loop-erased random walks (LERWs) are two ensembles of random paths with numerous applications in mathematics, statistical physics and quantum field theory. While SAWs are described by the n0n \to 0 limit of ϕ4\phi^4-theory with O(n)O(n)-symmetry, LERWs have no obvious field-theoretic description. We analyse two candidates for a field theory of LERWs, and discover a connection between the corresponding and a priori unrelated theories. The first such candidate is the O(n)O(n)-symmetric ϕ4\phi^4 theory at n=2n=-2 whose link to LERWs was known in two dimensions due to conformal field theory. Here it is established in arbitrary dimension via a perturbation expansion in the coupling constant. The second candidate is a field theory for charge-density waves pinned by quenched disorder, whose relation to LERWs had been conjectured earlier using analogies with Abelian sandpiles. We explicitly show that both theories yield identical results to 4-loop order and give both a perturbative and a non-perturbative proof of their equivalence. This allows us to compute the fractal dimension of LERWs to order ϵ5\epsilon^5 where ϵ=4d\epsilon=4-d. In particular, in d=3d=3 our theory gives zLERW(d=3)=1.6243±0.001z_{\rm LERW}(d=3)= 1.6243 \pm 0.001, in excellent agreement with the estimate z=1.62400±0.00005z = 1.624 00 \pm 0.00005 of numerical simulations.

Keywords

Cite

@article{arxiv.1802.08830,
  title  = {Field Theories for Loop-Erased Random Walks},
  author = {Kay Joerg Wiese and Andrei A. Fedorenko},
  journal= {arXiv preprint arXiv:1802.08830},
  year   = {2019}
}

Comments

18 pages, 223 figures. Added in v2: algebraic proof for the equivalence between the two theories. Explicit diagrammatic expression at 5 loop. v3: final version

R2 v1 2026-06-23T00:32:13.171Z