# Stability of receding traveling waves for a fourth order degenerate   parabolic free boundary problem

**Authors:** Manuel V. Gnann, Slim Ibrahim, and Nader Masmoudi

arXiv: 1704.06596 · 2020-08-25

## TL;DR

This paper analyzes the stability of receding traveling waves in a fourth-order degenerate parabolic free boundary problem related to thin-film equations, establishing well-posedness and stability results through maximal-regularity estimates.

## Contribution

It introduces a novel stability analysis for receding traveling waves in a fourth-order thin-film equation, addressing challenges due to the lack of a comparison principle.

## Key findings

- Proves maximal-regularity estimates for the linearized operator.
- Establishes well-posedness and stability of the nonlinear problem.
- Analyzes the different scalings near the contact line and at infinity.

## Abstract

Consider the thin-film equation $h_t + \left(h h_{yyy}\right)_y = 0$ with a zero contact angle at the free boundary, that is, at the triple junction where liquid, gas, and solid meet. Previous results on stability and well-posedness of this equation have focused on perturbations of equilibrium-stationary or self-similar profiles, the latter eventually wetting the whole surface. These solutions have their counterparts for the second-order porous-medium equation $h_t - (h^m)_{yy} = 0$, where $m > 1$ is a free parameter. Both porous-medium and thin-film equation degenerate as $h \searrow 0$, but the porous-medium equation additionally fulfills a comparison principle while the thin-film equation does not.   In this note, we consider traveling waves $h = \frac V 6 x^3 + \nu x^2$ for $x \ge 0$, where $x = y-V t$ and $V, \nu \ge 0$ are free parameters. These traveling waves are receding and therefore describe de-wetting, a phenomenon genuinely linked to the fourth-order nature of the thin-film equation and not encountered in the porous-medium case as it violates the comparison principle. The linear stability analysis leads to a linear fourth-order degenerate-parabolic operator for which we prove maximal-regularity estimates to arbitrary orders of the expansion in $x$ in a right-neighborhood of the contact line $x = 0$. This leads to a well-posedness and stability result for the corresponding nonlinear equation. As the linearized evolution has different scaling as $x \searrow 0$ and $x \to \infty$, the analysis is more intricate than in related previous works. We anticipate that our approach is a natural step towards investigating other situations in which the comparison principle is violated, such as droplet rupture.

## Full text

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## References

39 references — full list in the complete paper: https://tomesphere.com/paper/1704.06596/full.md

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Source: https://tomesphere.com/paper/1704.06596