English

Metastability for expanding bubbles on a sticky substrate

Probability 2020-07-20 v2 Mathematical Physics math.MP

Abstract

We study the dynamical behavior of a one dimensional interface interacting with a sticky unpenetrable substrate or wall. The interface is subject to two effects going in opposite directions. Contact between the interface and the substrate are given an energetic bonus while an external force with constant intensity pulls the interface away from the wall. Our interface is modeled by the graph of a one-dimensional nearest-neighbor path on Z+\mathbb{Z}_+, starting at 00 and ending at 00 after 2N2N steps, the wall corresponding to level-zero the horizontal axis. At equilibrium each path ξ=(ξx)x=02N\xi=(\xi_x)_{x=0}^{2N}, is given a probability proportional to λH(ξ)exp(σNA(ξ))\lambda^{H(\xi)} \exp(\frac{\sigma}{N}A(\xi)), where H(ξ):=#{x :ξx=0}H(\xi):=\#\{x \ : \xi_x=0\} and A(ξ)A(\xi) is the area enclosed between the path ξ\xi and the xx-axis. We then consider the classical heat-bath dynamics which equilibrates the value of each ξx\xi_x at a constant rate via corner-flip. Investigating the statics of the model, we derive the full phase diagram in λ\lambda and σ\sigma of this model, and identify the critical line which separates a localized phase where the pinning force sticks the interface to the wall and a delocalized one, for which the external force stabilizes ξ\xi around a deterministic shape at a macroscopic distance of the wall. On the dynamical side, we identify a second critical line, which separates a rapidly mixing phase (for which the system mixes in polynomial time) to a slow phase where the mixing time grows exponentially. In this slowly mixing regime we obtain a sharp estimate of the mixing time on the log\log scale, and provide evidences of a metastable behavior.

Keywords

Cite

@article{arxiv.2007.07832,
  title  = {Metastability for expanding bubbles on a sticky substrate},
  author = {Hubert Lacoin and Shangjie Yang},
  journal= {arXiv preprint arXiv:2007.07832},
  year   = {2020}
}

Comments

40 pages, 6 Figures

R2 v1 2026-06-23T17:08:45.036Z