# The Competition of Roughness and Curvature in Area-Constrained Polymer   Models

**Authors:** Riddhipratim Basu, Shirshendu Ganguly, and Alan Hammond

arXiv: 1704.07360 · 2018-11-14

## TL;DR

This paper investigates how local interface fluctuations and global curvature constraints interact in KPZ universality class models, revealing a new exponent triple for constrained paths in directed last passage percolation.

## Contribution

It introduces a novel analysis of area-constrained paths in KPZ models, showing a different set of fluctuation exponents than classical Brownian-based models.

## Key findings

- The local interface fluctuation exponent is 2/3.
- Facet lengths follow an exponent of 3/4.
- Inward deviation has an exponent of 1/2.

## Abstract

The competition between local Brownian roughness and global parabolic curvature experienced in many random interface models reflects an important aspect of the KPZ universality class. It may be summarised by an exponent triple $(1/2,1/3,2/3)$ representing local interface fluctuation, local roughness (or inward deviation) and convex hull facet length. The three effects arise, for example, in droplets in planar Ising models (Alexander, '01, Hammond, '11,'12). In this article, we offer a new perspective on this phenomenon. We consider directed last passage percolation model in the plane, a paradigmatic example in the KPZ universality class, and constrain the maximizing path under the additional requirement of enclosing an atypically large area. The interface suffers a constraint of parabolic curvature as before, but now its local structure is the KPZ fixed point polymer's rather than Brownian. The local interface fluctuation exponent is thus two-thirds rather than one-half. We prove that the facet lengths of the constrained path's convex hull are governed by an exponent of $3/4$, and inward deviation by an exponent of $1/2$. That is, the exponent triple is now $(2/3,1/2,3/4)$ in place of $(1/2,1/3,2/3)$. This phenomenon appears to be shared among various isoperimetrically extremal circuits in local randomness. Indeed, we formulate a conjecture to this effect concerning such circuits in supercritical percolation, whose Wulff-like first-order behaviour was recently established (Biskup, Louidor, Procaccia and Rosenthal, '12).

## Full text

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## Figures

7 figures with captions in the complete paper: https://tomesphere.com/paper/1704.07360/full.md

## References

29 references — full list in the complete paper: https://tomesphere.com/paper/1704.07360/full.md

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Source: https://tomesphere.com/paper/1704.07360