Difference between revisions of "Nanoparticle in a Nanofluid Film Spreading on a Surface"
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This research shows the solid-oil interactions in the presence of a silica nanoparticle aqueous suspension, using a combined differential and common reflected light interferometry by observing the three-phase contact region as presented in Figure 1. Figure 2 shows a sequence of photomicrographs depicting the development of the particle layering phenomenon during the film thinning process. It is shown that a photomicrograph depicting four different particle structural transitions inside the nanofluid film in Figure 3. Here, the experiments revealed that the nanofluid film thickness stability on a solid substrate depends on the film size. Figure 4 presents an example of a small oil drop, that shows that the nanofluid film formed between oil drop and the glass surface surrounded by the meniscus, indicated by the consecutive dark and bright Newton interference rings around the perophery of the film. The interferogram depicting the film-meniscus profile is shown in Figure 4C. Figure 5 shows the film-meniscus region profile corresponding to the maxima and minima in the interferogram. | This research shows the solid-oil interactions in the presence of a silica nanoparticle aqueous suspension, using a combined differential and common reflected light interferometry by observing the three-phase contact region as presented in Figure 1. Figure 2 shows a sequence of photomicrographs depicting the development of the particle layering phenomenon during the film thinning process. It is shown that a photomicrograph depicting four different particle structural transitions inside the nanofluid film in Figure 3. Here, the experiments revealed that the nanofluid film thickness stability on a solid substrate depends on the film size. Figure 4 presents an example of a small oil drop, that shows that the nanofluid film formed between oil drop and the glass surface surrounded by the meniscus, indicated by the consecutive dark and bright Newton interference rings around the perophery of the film. The interferogram depicting the film-meniscus profile is shown in Figure 4C. Figure 5 shows the film-meniscus region profile corresponding to the maxima and minima in the interferogram. | ||
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==[[Discussion]]== | ==[[Discussion]]== | ||
In this paper, the experimental results of the nanoparticle self-ordering and stepwise thinning of the nanofluid film fromed between an oil drop and a solid surface are reported. This also presents the measured contact angle of film-meniscus and thickness corresponding to the number of particle layers on a solid surface. These were used for getting the film energy due to the nanoparticle layering within the nanofluid film. | In this paper, the experimental results of the nanoparticle self-ordering and stepwise thinning of the nanofluid film fromed between an oil drop and a solid surface are reported. This also presents the measured contact angle of film-meniscus and thickness corresponding to the number of particle layers on a solid surface. These were used for getting the film energy due to the nanoparticle layering within the nanofluid film. | ||
Revision as of 03:52, 20 April 2012
Original entry by Hyerim Hwang, AP 226, Spring 2012. not finished
Reference
Alex Nikolov, Kirti Kondiparty, and Darsh Wasan, "Nanoparticle Self-Structuring in a Nanofluid Film Spreading on a Solid Surface", Langmuir 2010 26(11), 7665-7670
Keywords
Thin film stability, Nanofluids, Disjoining pressure
Introduction
This paper investigates the complex mechanism involved in the solid-nanofluid-oil interactions by directly observing the phenomenon of nanoparticle self-layering due to confinement of nanoparticles in a thin film. This research also shows that the effect of film size on stability of nanolfluid films on a solid substrate.
Results
This research shows the solid-oil interactions in the presence of a silica nanoparticle aqueous suspension, using a combined differential and common reflected light interferometry by observing the three-phase contact region as presented in Figure 1. Figure 2 shows a sequence of photomicrographs depicting the development of the particle layering phenomenon during the film thinning process. It is shown that a photomicrograph depicting four different particle structural transitions inside the nanofluid film in Figure 3. Here, the experiments revealed that the nanofluid film thickness stability on a solid substrate depends on the film size. Figure 4 presents an example of a small oil drop, that shows that the nanofluid film formed between oil drop and the glass surface surrounded by the meniscus, indicated by the consecutive dark and bright Newton interference rings around the perophery of the film. The interferogram depicting the film-meniscus profile is shown in Figure 4C. Figure 5 shows the film-meniscus region profile corresponding to the maxima and minima in the interferogram.
Discussion
In this paper, the experimental results of the nanoparticle self-ordering and stepwise thinning of the nanofluid film fromed between an oil drop and a solid surface are reported. This also presents the measured contact angle of film-meniscus and thickness corresponding to the number of particle layers on a solid surface. These were used for getting the film energy due to the nanoparticle layering within the nanofluid film.
