Interfaces and wetting transition on the half plane. Exact results from field theory

TL;DR

This paper uses two-dimensional field theory to derive exact results on interface behavior and wetting transitions in ferromagnetic systems near criticality, revealing how boundary conditions influence phase separation and interface positioning.

Contribution

It provides the first exact asymptotic analysis of interface profiles and wetting phenomena in half-plane ferromagnetic systems using field theory, connecting microscopic boundary effects to macroscopic wetting behavior.

Findings

Exact asymptotics of magnetization profile perpendicular to boundary.

Presence and properties of boundary-pinned interfaces.

Relation between contact angle and boundary reflection pole.

Abstract

We consider the scaling limit of a generic ferromagnetic system with a continuous phase transition, on the half plane with boundary conditions leading to the equilibrium of two different phases below criticality. We use general properties of low energy two-dimensional field theory to determine exact asymptotics of the magnetization profile perperdicularly to the boundary, to show the presence of an interface with endpoints pinned to the boundary, and to determine its passage probability. The midpoint average distance of the interface from the boundary grows as the square root of the distance between the endpoints, unless the reflection amplitude of the bulk excitations on the boundary possesses a stable bound state pole. The contact angle of the phenomenological wetting theory is exactly related to the location of this pole. Results available from the lattice solution of the Ising model are recovered as a particular case.