AI Article Synopsis
- Microfluidic channels are important for controlling nanoscale objects like nanoparticles and DNA but are challenging to design due to high fabrication costs and complex experiments.
- Numerical methods can help predict the performance of these channels by addressing issues like nanowire alignment and cell adhesion, offering a more cost-effective alternative.
- This paper presents an updated immersed finite element method that simulates nanoparticle movements, examines the effects of Brownian motion under varying temperatures, and predicts improved focusing efficiency in a double lens system.
Article Abstract
Microfluidic channels have received much attention because they can be used to control and transport nanoscale objects such as nanoparticles, nanowires, carbon nanotubes, DNA and cells. However, so far, practical channels have not been easy to design because they require very expensive fabrication and sensitive experiments. Numerical approaches can be alternatives or supplementary measures to predict the performance of new channels because they efficiently explain nanoscale multi-physics phenomena and successfully solve nanowire alignment and cell adhesion problems. In this paper, a newly updated immersed finite element method that accounts for collision force and Brownian motion as well as fluid-solid interaction is proposed, and is applied to simulate nanoparticle movements in a microfluidic channel. As part of the simulation, Brownian motion effects in a single nanoparticle focusing lens system are examined under different temperature conditions, and the resulting transport efficiencies are discussed. Furthermore, nanoparticle movements in a double focusing lens system are predicted to show the enhancement of focusing efficiency.
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| http://dx.doi.org/10.1166/jnn.2011.3263 | DOI Listing |
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