One-dimensional polymers in random environments: stretching vs. folding
Abstract
In this article we study a \emph{non-directed polymer model} on , that is a one-dimensional simple random walk placed in a random environment. More precisely, the law of the random walk is modified by the exponential of the sum of "rewards" (or penalities) sitting on the range of the random walk, where are i.i.d.\ random variables (the disorder), and where (disorder strength) and (external field) are two parameters. When , this corresponds to a random walk penalized by its range; when , this corresponds to the "standard" polymer model in random environment, except that it is non-directed. In this work, we allow the parameters to vary according to the length of the random walk, and we study in detail the competition between the \emph{stretching effect} of the disorder, the \emph{folding effect} of the external field (if ), and the \emph{entropy cost} of atypical trajectories. We prove a complete description of the (rich) phase diagram. For instance, in the case of the non-directed polymer, if ha a finite second moment, we find a transversal fluctuation exponent , and we identify the limiting distribution of the rescaled log-partition function.
Cite
@article{arxiv.2002.06899,
title = {One-dimensional polymers in random environments: stretching vs. folding},
author = {Quentin Berger and Chien-Hao Huang and Niccolo Torri and Ran Wei},
journal= {arXiv preprint arXiv:2002.06899},
year = {2022}
}
Comments
44 pages, 5 figures