Approach to universal self-similar attractor for the levelling of thin liquid films

Michael Benzaquen; Paul Fowler; Laetitia Jubin; Thomas Salez; Kari Dalnoki-Veress; Elie Raphaël

doi:10.1039/c4sm01483a

Approach to universal self-similar attractor for the levelling of thin liquid films

Michael Benzaquen
, Paul Fowler
, Laetitia Jubin
, Thomas Salez
, Kari Dalnoki-Veress
, Elie Raphaël

Research output: Contribution to journal › Article › peer-review

Abstract

We compare the capillary levelling of a random surface perturbation on a thin polystyrene film with a theoretical study on the two-dimensional capillary-driven thin film equation. Using atomic force microscopy, we follow the time evolution of samples prepared with different initial perturbations of the free surface. In particular, we show that the surface profiles present long term self-similarity, and furthermore, that they converge to a universal self-similar attractor that only depends on the volume of the perturbation, consistent with the theory. Finally, we look at the convergence time for the different samples and find very good agreement with the analytical predictions.

Original language	English
Pages (from-to)	8608-8614
Number of pages	7
Journal	Soft Matter
Volume	10
Issue number	43
DOIs	https://doi.org/10.1039/c4sm01483a
Publication status	Published - 21 Nov 2014
Externally published	Yes

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title = "Approach to universal self-similar attractor for the levelling of thin liquid films",

abstract = "We compare the capillary levelling of a random surface perturbation on a thin polystyrene film with a theoretical study on the two-dimensional capillary-driven thin film equation. Using atomic force microscopy, we follow the time evolution of samples prepared with different initial perturbations of the free surface. In particular, we show that the surface profiles present long term self-similarity, and furthermore, that they converge to a universal self-similar attractor that only depends on the volume of the perturbation, consistent with the theory. Finally, we look at the convergence time for the different samples and find very good agreement with the analytical predictions.",

author = "Michael Benzaquen and Paul Fowler and Laetitia Jubin and Thomas Salez and Kari Dalnoki-Veress and Elie Rapha{\"e}l",

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AU - Benzaquen, Michael

AU - Fowler, Paul

AU - Jubin, Laetitia

AU - Salez, Thomas

AU - Dalnoki-Veress, Kari

AU - Raphaël, Elie

PY - 2014/11/21

Y1 - 2014/11/21

N2 - We compare the capillary levelling of a random surface perturbation on a thin polystyrene film with a theoretical study on the two-dimensional capillary-driven thin film equation. Using atomic force microscopy, we follow the time evolution of samples prepared with different initial perturbations of the free surface. In particular, we show that the surface profiles present long term self-similarity, and furthermore, that they converge to a universal self-similar attractor that only depends on the volume of the perturbation, consistent with the theory. Finally, we look at the convergence time for the different samples and find very good agreement with the analytical predictions.

AB - We compare the capillary levelling of a random surface perturbation on a thin polystyrene film with a theoretical study on the two-dimensional capillary-driven thin film equation. Using atomic force microscopy, we follow the time evolution of samples prepared with different initial perturbations of the free surface. In particular, we show that the surface profiles present long term self-similarity, and furthermore, that they converge to a universal self-similar attractor that only depends on the volume of the perturbation, consistent with the theory. Finally, we look at the convergence time for the different samples and find very good agreement with the analytical predictions.

U2 - 10.1039/c4sm01483a

DO - 10.1039/c4sm01483a

M3 - Article

AN - SCOPUS:84907992131

SN - 1744-683X

VL - 10

SP - 8608

EP - 8614

JO - Soft Matter

JF - Soft Matter

IS - 43

ER -

Approach to universal self-similar attractor for the levelling of thin liquid films

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