English

KPZ models: height-gradient fluctuations and the tilt method

Statistical Mechanics 2021-06-11 v2

Abstract

When a growing interface belonging to the KPZ universality class is tilted with average slope mm, its average velocity increases in Λ2m2\frac{\Lambda}{2}\,m^2, where Λ\Lambda is related to the nonlinear coefficient λ\lambda of the KPZ equation. Nevertheless, a necessary condition for this association to hold true is that the mean square height-gradient increases in bm2b\, m^2 when the interface is tilted. For the continuous KPZ equation b=1b = 1 and the relation Λ=λ\Lambda=\lambda is achieved. In this work, we study the local fluctuations of the height gradient through an analysis of the values of bb. We show that, for 1-dimensional discrete KPZ models, bb has a power-law dependence with the discretization step ss chosen to calculate the height gradient and bb goes to 11 as ss increases. Its power-law exponent γb\gamma_b matches the exponent associated with the finite-size corrections of the interface average velocity, i.e.\textit{i.e.} γb=2(ζ1)\gamma_b=2(\zeta-1), where ζ\zeta is the global roughness exponent. We also show how, for restricted (unrestricted) growth models, the value of bb goes to 11 from below (above) as ss increases.

Keywords

Cite

@article{arxiv.1711.09652,
  title  = {KPZ models: height-gradient fluctuations and the tilt method},
  author = {M. F. Torres and R. C. Buceta},
  journal= {arXiv preprint arXiv:1711.09652},
  year   = {2021}
}

Comments

9 pages, 3 figures. We study in more detail the local fluctuations of the height gradient with the measurement window and modify the work and conclusions to reflect that

R2 v1 2026-06-22T22:57:47.395Z