# Replica Bethe Ansatz solution to the Kardar-Parisi-Zhang equation on the   half-line

**Authors:** Alexandre Krajenbrink, Pierre Le Doussal

arXiv: 1905.05718 · 2020-03-04

## TL;DR

This paper provides an exact replica Bethe ansatz solution to the KPZ equation on the half-line, deriving explicit distributions for the height at the boundary under various initial conditions and boundary parameters.

## Contribution

It extends the exact solutions of the KPZ equation to half-line geometries with boundary conditions, revealing new distributional results and phase transitions.

## Key findings

- Exact Laplace transform of height distribution at all times
- Explicit Tracy-Widom distributions for different boundary conditions
- Identification of a critical point with a transition kernel

## Abstract

We consider the Kardar-Parisi-Zhang (KPZ) equation for the stochastic growth of an interface of height $h(x,t)$ on the positive half line with boundary condition $\partial_x h(x,t)|_{x=0}=A$. It is equivalent to a continuum directed polymer (DP) in a random potential in half-space with a wall at $x=0$ either repulsive $A>0$, or attractive $A<0$. We provide an exact solution, using replica Bethe ansatz methods, to two problems which were recently proved to be equivalent [Parekh, arXiv:1901.09449]: the droplet initial condition for arbitrary $A \geqslant -1/2$, and the Brownian initial condition with a drift for $A=+\infty$ (infinite hard wall). We study the height at $x=0$ and obtain (i) at all time the Laplace transform of the distribution of its exponential (ii) at infinite time, its exact probability distribution function (PDF). These are expressed in two equivalent forms, either as a Fredholm Pfaffian with a matrix valued kernel, or as a Fredholm determinant with a scalar kernel. For droplet initial conditions and $A> - \frac{1}{2}$ the large time PDF is the GSE Tracy-Widom distribution. For $A= \frac{1}{2}$, the critical point at which the DP binds to the wall, we obtain the GOE Tracy-Widom distribution. In the critical region, $A+\frac{1}{2} = \epsilon t^{-1/3} \to 0$ with fixed $\epsilon = \mathcal{O}(1)$, we obtain a transition kernel continuously depending on $\epsilon$. Our work extends the results obtained previously for $A=+\infty$, $A=0$ and $A=- \frac{1}{2}$.

## Full text

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## References

76 references — full list in the complete paper: https://tomesphere.com/paper/1905.05718/full.md

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Source: https://tomesphere.com/paper/1905.05718