English

Localization of the continuum directed random polymer

Probability 2022-04-05 v2 Mathematical Physics math.MP

Abstract

We consider the continuum directed random polymer (CDRP) model that arises as a scaling limit from 1+11+1 dimensional directed polymers in the intermediate disorder regime. We show that for a point-to-point polymer of length tt and any p(0,1)p\in (0,1), the quenched density of the point on the path which is ptpt distance away from the origin when centered around its random mode Mp,t\mathcal{M}_{p,t} converges in law to an explicit random density function as tt\to\infty without any scaling. Similarly, in the case of point-to-line polymers of length tt, the quenched density of the endpoint of the path when centered around its random mode M,t\mathcal{M}_{*,t} converges in law to an explicit random density. The limiting random densities are proportional to eRσ(x)e^{-\mathcal{R}_\sigma(x)} where Rσ(x)\mathcal{R}_\sigma(x) is a two-sided 3D Bessel process with appropriate diffusion coefficient σ\sigma. In addition, the laws of the random modes M,t\mathcal{M}_{*,t}, Mp,t\mathcal{M}_{p,t} themselves converge in distribution upon t2/3t^{2/3} scaling to the maximizer of Airy2\operatorname{Airy}_2 process minus a parabola and points on the geodesics of the directed landscape respectively. Our localization results stated above provide an affirmative case of the folklore "favorite region" conjecture. Our proof techniques also allow us to prove properties of the KPZ equation such as ergodicity and limiting Bessel behaviors around the maximum.

Keywords

Cite

@article{arxiv.2203.03607,
  title  = {Localization of the continuum directed random polymer},
  author = {Sayan Das and Weitao Zhu},
  journal= {arXiv preprint arXiv:2203.03607},
  year   = {2022}
}

Comments

63 pages, 10 figures; Minor edits before submission to journal

R2 v1 2026-06-24T10:05:00.957Z