Roles of gas in capillary filling of nanoslits

Control and understanding of flows inside fabricated nanochannels is rich in potential applications, but nanoscale physics of fluids remains to be clarified even for the simple case of spontaneous capillary filling. This paper reports an experimental and modelling investigation of the role of gas on...

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Bibliographic Details
Published in:Soft matter 2012-01, Vol.8 (41), p.1738-1749
Main Authors: Chauvet, Fabien, Geoffroy, Sandrine, Hamoumi, Abdelkrim, Prat, Marc, Joseph, Pierre
Format: Article
Language:English
Subjects:
Bubbles
Capillarity
Chemical and Process Engineering
Computer Science
Engineering Sciences
Fluid Dynamics
Fluid mechanics
Fluids mechanics
Hardware Architecture
Liquids
Materials
Mechanics
Nanocomposites
Nanomaterials
Nanostructure
Natural gas
Physics
Slits
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Summary:Control and understanding of flows inside fabricated nanochannels is rich in potential applications, but nanoscale physics of fluids remains to be clarified even for the simple case of spontaneous capillary filling. This paper reports an experimental and modelling investigation of the role of gas on the capillary filling kinetics slowdown in nanoslits (depth going from 20 nm to 400 nm) compared to Washburn's prediction. First, the role of gas through the usually observed trapped bubbles during a nanoslits capillary filling is analysed thanks to experiments realized with water, ethanol and silicone oil in silicon-glass nanochannels. Bubbles are trapped only when slit depth is below a liquid-dependent threshold. This is interpreted as possible contact line pinning strength varying with wettability. Stagnant trapped bubbles lifetime is investigated for the three liquids used. Experimental results show that bubbles are first compressed because of the increasing local liquid pressure. Once the gas bubble pressure is sufficiently high, gas dissolution induces the final bubble collapse. Influence of the bubbles' presence on the capillary filling kinetics is analysed by estimating viscous resistance induced by the bubbles using an effective medium approach (Brinkman approximation). Surprisingly, the bubbles' presence is found to have a very minor effect on nanoslits capillary filling kinetics. Second, the transient gas pressure profile between the advancing meniscus and the channel exit is computed numerically taking into account gas compressibility. A non-negligible over-pressure ahead of the meniscus is found for nano-scale slit capillary filling. Considering the possible presence of precursor films, reducing cross-section for gas flow, leads to a capillary filling kinetics slowdown comparable to the ones measured experimentally. Liquid imbibition into a nanoslit is characterized by significant pressurization of gas and trapping of bubbles. Both effects are not sufficient to explain the filling kinetics slowdown.
ISSN:1744-683X
1744-6848
DOI:10.1039/c2sm25982f