Capillary filling in nanochannels : modeling, fabrication and experiments
While capillary filling in channels of micrometers scale is experimentally verified to obey Washburn's law well, the speed of capillary filling in nanochannels is noticeably lower than described by Washburn's formula. This article reports the theoretical and experimental results on capilla...
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sg-ntu-dr.10356-938832023-03-04T17:16:35Z Capillary filling in nanochannels : modeling, fabrication and experiments Phan, Vinh-Nguyen Joseph, Pierre Djeghlaf, Lyes Allouch, Alaa el dine Bourrier, David Abgrall, Patrick Gue, Anne-Marie Yang, Chun Nguyen, Nam-Trung School of Mechanical and Aerospace Engineering DRNTU::Engineering::Mechanical engineering While capillary filling in channels of micrometers scale is experimentally verified to obey Washburn's law well, the speed of capillary filling in nanochannels is noticeably lower than described by Washburn's formula. This article reports the theoretical and experimental results on capillary filling in open-end and closed-end nanochannels. Nanochannels of 45 nm and 80 nm depth, 10 μm width, were etched in silicon and bonded to a glass cover. Experiments on filling of non-electrolytic liquid in silicon nanochannels were carried out. The filling processes were observed and recorded. To estimate the influence of electrokinetics, a mathematical model to calculate the electroviscous effect was established. This model shows that the contribution of the electroviscous effect in the reduction of filling speed is small. This result also agrees well with previous theoretical work on the electroviscous effect. That means that besides the electroviscous effect, there are other phenomena that contribute to the reduction of capillary filling speed in a nanochannel, such as air bubbles formation. Experimental investigation of capillary filling in open-end and closed-end nanochannels with different lengths was performed. The filling processes of ethanol and isopropanol and the behavior of the trapped air were recorded and evaluated. Analytical models based on the continuum assumption were used to evaluate the experimental data. We observed that the filling process consists of two stages. At the initial stage, experimental data agree well with the theoretical model, but with a higher apparent viscosity. In the final stage, condensation of the liquid phase and dissolution of the gas phase lead to total filling of the nanochannel. The observed phenomena are important for understanding the behavior of multiphase systems in nanochannels. Accepted version 2012-04-12T08:34:11Z 2019-12-06T18:47:06Z 2012-04-12T08:34:11Z 2019-12-06T18:47:06Z 2011 2011 Journal Article Phan, V. N., Joseph, P., Djeghlaf, L., Allouch, A. E. D., Bourrier, D., Abgrall, P., et al. (2011). Capillary Filling in Nanochannels – Modeling, Fabrication and Experiments. Heat Transfer Engineering, 32(7-8), 624-635. https://hdl.handle.net/10356/93883 http://hdl.handle.net/10220/7771 10.1080/01457632.2010.509756 159373 en Heat transfer engineering © 2011 Taylor and Francis Group. This is the author created version of a work that has been peer reviewed and accepted for publication by Heat Transfer Engineering, Taylor and Francis Group. It incorporates referee’s comments but changes resulting from the publishing process, such as copyediting, structural formatting, may not be reflected in this document. The published version is available at: [DOI: http://dx.doi.org/10.1080/01457632.2010.509756]. application/pdf |
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DRNTU::Engineering::Mechanical engineering Phan, Vinh-Nguyen Joseph, Pierre Djeghlaf, Lyes Allouch, Alaa el dine Bourrier, David Abgrall, Patrick Gue, Anne-Marie Yang, Chun Nguyen, Nam-Trung Capillary filling in nanochannels : modeling, fabrication and experiments |
| description |
While capillary filling in channels of micrometers scale is experimentally verified to obey Washburn's law well, the speed of capillary filling in nanochannels is noticeably lower than described by Washburn's formula. This article reports the theoretical and experimental results on capillary filling in open-end and closed-end nanochannels. Nanochannels of 45 nm and 80 nm depth, 10 μm width, were etched in silicon and bonded to a glass cover. Experiments on filling of non-electrolytic liquid in silicon nanochannels were carried out. The filling processes were observed and recorded. To estimate the influence of electrokinetics, a mathematical model to calculate the electroviscous effect was established. This model shows that the contribution of the electroviscous effect in the reduction of filling speed is small. This result also agrees well with previous theoretical work on the electroviscous effect. That means that besides the electroviscous effect, there are other phenomena that contribute to the reduction of capillary filling speed in a nanochannel, such as air bubbles formation. Experimental investigation of capillary filling in open-end and closed-end nanochannels with different lengths was performed. The filling processes of ethanol and isopropanol and the behavior of the trapped air were recorded and evaluated. Analytical models based on the continuum assumption were used to evaluate the experimental data. We observed that the filling process consists of two stages. At the initial stage, experimental data agree well with the theoretical model, but with a higher apparent viscosity. In the final stage, condensation of the liquid phase and dissolution of the gas phase lead to total filling of the nanochannel. The observed phenomena are important for understanding the behavior of multiphase systems in nanochannels. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Phan, Vinh-Nguyen Joseph, Pierre Djeghlaf, Lyes Allouch, Alaa el dine Bourrier, David Abgrall, Patrick Gue, Anne-Marie Yang, Chun Nguyen, Nam-Trung |
| format |
Article |
| author |
Phan, Vinh-Nguyen Joseph, Pierre Djeghlaf, Lyes Allouch, Alaa el dine Bourrier, David Abgrall, Patrick Gue, Anne-Marie Yang, Chun Nguyen, Nam-Trung |
| author_sort |
Phan, Vinh-Nguyen |
| title |
Capillary filling in nanochannels : modeling, fabrication and experiments |
| title_short |
Capillary filling in nanochannels : modeling, fabrication and experiments |
| title_full |
Capillary filling in nanochannels : modeling, fabrication and experiments |
| title_fullStr |
Capillary filling in nanochannels : modeling, fabrication and experiments |
| title_full_unstemmed |
Capillary filling in nanochannels : modeling, fabrication and experiments |
| title_sort |
capillary filling in nanochannels : modeling, fabrication and experiments |
| publishDate |
2012 |
| url |
https://hdl.handle.net/10356/93883 http://hdl.handle.net/10220/7771 |
| _version_ |
1759857621990375424 |