Bubble Nucleation and Growth in a Force-Driven Flowing Liquid Film Under Controlled Pressure by Molecular Dynamics Simulation
Ziqi Li, Ziqi Cai, Zhengming Gao

TL;DR
This paper uses molecular simulations to study how bubbles form and grow in a flowing liquid film under pressure and heating, revealing how these factors affect bubble behavior at the molecular level.
Contribution
The study provides new molecular-level insights into how pressure, temperature, and flow interact to influence bubble nucleation and growth in flowing liquid films.
Findings
Higher system pressure delays bubble nucleation, while higher substrate temperature accelerates it.
Applied forces from 4.0×10−7 eV/Å to 1.0×10−6 eV/Å promote nucleation and bubble growth, but higher forces suppress nucleation due to increased instability.
Liquid flow has a non-monotonic effect on bubble nucleation under fixed pressure and temperature.
Abstract
Bubble nucleation in flowing liquid films is a common interfacial phenomenon affecting the heat and mass transfer at the solid–liquid interfaces in many thermal and functional material production processes, yet realizing its molecular-scale mechanisms under coupled flow, pressure, and heating conditions is important. In this study, molecular dynamics simulations are performed to investigate the bubble nucleation and growth in a liquid argon film on a heated platinum substrate under controlled pressure, with liquid flow driven by an applied body force. Bubble evolution is analyzed by the nucleation time, critical nucleation volume, bubble volume variation, and migration of the bubble’s center of mass. The results show that system pressure and substrate temperature dominantly regulate the nucleation: increasing pressure delays nucleation, whereas increasing substrate temperature…
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Taxonomy
TopicsFluid Dynamics and Thin Films · Nanomaterials and Printing Technologies · Solidification and crystal growth phenomena
