M. Aghdasi , M. Nazari , S. Yonesi Holari , Nicole N. Hashemi
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引用次数: 0
摘要
介电泳(DEP)是在微流体设备中操纵颗粒的一种有效技术。电泳力取决于电场的频率和平方梯度,以及流体和颗粒的介电性质。通过调整这些因素,可以设计出高效的微粒操纵系统。本研究旨在开发一种利用双频 DEP 力捕获粒子的高效微系统。微流控系统分为聚焦和吸引两部分。聚焦部分的负 DEP(nDEP)力将颗粒集中在微通道轴线附近。吸引区的正 DEP(pDEP)力则通过电极将颗粒吸入内腔。总的来说,这种设计的主要优点是能最大限度地捕获进入的微粒(捕获率超过 95%),而不管其初始位置如何。在这项研究中,首先进行了三维数值建模,对微粒进行分类和捕获。然后,在实验室中设计、制造和测试了一个微型芯片,以验证结果并确认微流体系统的行为。最后,进行了参数研究,以确定微流控系统中电场的最佳电压范围。
Designing a new microchannel to collect microparticles using dielectrophoretic forces: Numerical and experimental investigation
Dielectrophoresis (DEP) is an effective technique for manipulating particles in microfluidic devices. The DEP force depends on the frequency and square gradient of the electric field, as well as the fluid and particle dielectric properties. An efficient system for manipulating particles can be designed by adjusting these factors. This study aims to develop an efficient microsystem for particle trapping using dual-frequency DEP force. The microfluidic system is divided into two parts of focusing and attracting. The negative DEP (nDEP) force in the focusing part concentrates particles near the microchannel axis. The positive DEP (pDEP) force in the attractive area then absorbs particles into the internal chamber via electrodes. In general, the main advantage of the present design is the maximum trapping of incoming particles (with a trapping rate of over 95%) regardless of their initial location. In this study, numerical modeling was first done in three dimensions to sort and trap the microparticles. Then, a microchip was designed, built, and tested in a laboratory to validate the results and confirm the microfluidic system behavior. Finally, a parametric study was conducted to figure out the best voltage range of the electric fields in the microfluidic system.
期刊介绍:
The Journal of Electrostatics is the leading forum for publishing research findings that advance knowledge in the field of electrostatics. We invite submissions in the following areas:
Electrostatic charge separation processes.
Electrostatic manipulation of particles, droplets, and biological cells.
Electrostatically driven or controlled fluid flow.
Electrostatics in the gas phase.