利用纳米纹理表面减少微通道压降的挑战

Tara Dalton, Marc Scott Hodes, Cormac Eason, P. Kolodner, Ryan Enright, T. Krupenkin
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引用次数: 5

摘要

硅加工和微机械加工的进步现在允许生产控制粗糙度超疏水表面所需的微纳米尺度特征的一致制造。超疏水表面结合了粗糙度和低表面能的特点,使材料的润湿性大大降低,从而减少了水动力阻力。因此,它们代表了一种有前途的技术,以减少微通道流动阻力;微流体系统的主要技术问题。然而,在不可逆的润湿转变发生之前,超疏水表面所能承受的压力有限,导致减阻效果丧失。更重要的是初步观察,即使在超疏水表面不可逆地湿润之前,超疏水表面上的阻力减少可能会因三相接触线位置的细微变化而受到损害。微几何形状对传热的积极影响是众所周知的。将这种现象与超疏水表面相结合,可以减少流动阻力,这可能是电子冷却等领域向前迈出的重要一步。然而,超疏水表面的理论模型由于需要在多尺度上的高分辨率而变得复杂。本文旨在介绍目前的结果,并讨论在微通道中实现超疏水表面,特别是纳米结构的帖子的问题
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Challenges in using nano-textured surfaces to reduce pressure drop through microchannels
Advances in silicon processing and micro-machining now allow the consistent manufacture of micro- and nanoscale features necessary for the production of controlled roughness superhydrophobic surfaces. Superhydrophobic surfaces combine roughness features with low surface energy to create materials with substantially decreased wettability and, subsequently, reduced hydrodynamic drag. Thus, they represent a promising technology for reducing microchannel flow resistance; a major technical issue in microfluidic systems. In there, however, limits to the pressure a superhydrophobic surface can support before irreversible wetting transition occurs, leading to a loss of the drag-reducing effect. Of greater importance are preliminary observations that, even before a superhydrophobic surface wets irreversibly, the drag reduction over a superhydrophobic surface may be compromised by subtle changes in the three-phase contact line position. The positive impact of micro-geometries on heat transfer is well known. Coupling this phenomenon with superhydrophobic surfaces to reduce flow resistance, could represent a significant step forward in areas such as electronics cooling. However, theoretical models of superhydrophobic surfaces are complex due to the requirement for high resolution on multiple scales. This paper aims to present current results and discuss issues in implementing superhydrophobic surfaces, specifically nano-structured posts, in a microchannel
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