Yi-Kuen Lee scite author profile

Yi-Kuen Lee

4Publications

40Citation Statements Received

52Citation Statements Given

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Affiliations

Hong Kong University of Science and Technology, University of Hong Kong, University of California, Los Angeles

Publications

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Static and dynamic characterization of robust superhydrophobic surfaces built from nano-flowers on silicon micro-post arrays

Chen

Xiao

Chan

et al. 2010

J. Micromech. Microeng.

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Superhydrophobic nano-flower surfaces were fabricated using MEMS technology and microwave plasma-enhanced chemical vapor deposition (MPCVD) of carbon nanotubes on silicon micro-post array surfaces. The nano-flower structures can be readily formed within 1-2 min on the micro-post arrays with the spacing ranging from 25 to 30 μm. The petals of the nano-flowers consisted of clusters of multi-wall carbon nanotubes. Patterned nano-flower structures were characterized using various microscopy techniques. After MPCVD, the apparent contact angle (160 ± 0.2 • ), abbreviated as ACA (defined as the measured angle between the apparent solid surface and the tangent to the liquid-fluid interface), of the nano-flower surfaces increased by 139% compared with that of the silicon micro-post arrays. The measured ACA of the nano-flower surface is consistent with the predicted ACA from a modified Cassie-Baxter equation. A high-speed CCD camera was used to study droplet impact dynamics on various micro/nanostructured surfaces. Both static testing (ACA and sliding angle) and droplet impact dynamics demonstrated that, among seven different micro/nanostructured surfaces, the nano-flower surfaces are the most robust superhydrophobic surfaces.

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Characterization of a MEMS-Fabricated Mixing Device

Lee

Tabeling

Shih

et al. 2000

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This paper discusses the fabrication and the characterization of a MEMS-based micromixer. Active perturbations provided by a pressure source/sink system are used to enhance the mixing between two fluid streams. From our preliminary test, it appears that an effective mixing is possible through the generation of chaotic-like distortions at the interface between two streams. A numerical simulation based on a kinematical model reveals a similar behavior under the same condition.

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Creep of parylene-C film

Lin

Deng

Lam

et al. 2011

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Study of piezoresistance effect of carbon nanotube-PDMS composite materials for nanosensors

Lü

Bermak

et al. 2007

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Yi-Kuen Lee

Static and dynamic characterization of robust superhydrophobic surfaces built from nano-flowers on silicon micro-post arrays

Characterization of a MEMS-Fabricated Mixing Device

Creep of parylene-C film

Study of piezoresistance effect of carbon nanotube-PDMS composite materials for nanosensors

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