Saved in:
Bibliographic Details
Main Authors: Rahman, Muhammad Rizwanur, Shen, Li, Ewen, James P., Heyes, D. M., Dini, Daniele, Smith, E. R.
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2311.00419
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866913433433145344
author Rahman, Muhammad Rizwanur
Shen, Li
Ewen, James P.
Heyes, D. M.
Dini, Daniele
Smith, E. R.
author_facet Rahman, Muhammad Rizwanur
Shen, Li
Ewen, James P.
Heyes, D. M.
Dini, Daniele
Smith, E. R.
contents Thin films, bubbles and membranes are central to numerous natural and engineering processes, i.e., in thin-film solar cells, coatings, biosensors, electrowetting displays, foams, and emulsions. Yet, the characterization and an adequate understanding of their rupture is limited by the scarcity of atomic detail. We present here the complete life-cycle of freely suspended films using non-equilibrium molecular dynamics simulations of a simple atomic fluid free of surfactants and surface impurities, thus isolating the fundamental rupture mechanisms. Counter to the conventional notion that rupture occurs randomly, we discovered a short-term 'memory' by rewinding in time from a rupture event, extracting deterministic behaviors from apparent stochasticity. A comprehensive investigation of the key rupture-stages including both unrestrained and frustrated propagation is made - characterization of the latter leads to a first-order correction to the classical film-retraction theory. Furthermore, the highly resolved time window reveals that the different modes of the morphological development, typically characterized as heterogeneous nucleation and spinodal decomposition, continuously evolve seamlessly with time from one into the other.
format Preprint
id arxiv_https___arxiv_org_abs_2311_00419
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Life and Death of a Thin Liquid Film
Rahman, Muhammad Rizwanur
Shen, Li
Ewen, James P.
Heyes, D. M.
Dini, Daniele
Smith, E. R.
Fluid Dynamics
Thin films, bubbles and membranes are central to numerous natural and engineering processes, i.e., in thin-film solar cells, coatings, biosensors, electrowetting displays, foams, and emulsions. Yet, the characterization and an adequate understanding of their rupture is limited by the scarcity of atomic detail. We present here the complete life-cycle of freely suspended films using non-equilibrium molecular dynamics simulations of a simple atomic fluid free of surfactants and surface impurities, thus isolating the fundamental rupture mechanisms. Counter to the conventional notion that rupture occurs randomly, we discovered a short-term 'memory' by rewinding in time from a rupture event, extracting deterministic behaviors from apparent stochasticity. A comprehensive investigation of the key rupture-stages including both unrestrained and frustrated propagation is made - characterization of the latter leads to a first-order correction to the classical film-retraction theory. Furthermore, the highly resolved time window reveals that the different modes of the morphological development, typically characterized as heterogeneous nucleation and spinodal decomposition, continuously evolve seamlessly with time from one into the other.
title Life and Death of a Thin Liquid Film
topic Fluid Dynamics
url https://arxiv.org/abs/2311.00419