In this paper several electrodes architectures are modeled, implemented and compared in order to optimize the integration of hybrid micro-system for lab-on-a-chips (LoC). This study highlights the limitations of finite element simulations for a hybrid and complex micro-systems and propose new approach to overpass some fabrication constraints in a LoC design. The proposed LoC is based on dielectrophoresis for cell manipulation and capacitive sensing architecture. Particles used in this study has a diameter less than 10m which is close to the electrode dimensions. In this case conventional dielectrophoresis theory has some limitations. In order to handle particles in the range of micrometers, we describe four different electrode architectures which are the conventional square electrode array whose dimensions are 10m x 10m, the 10m width L-shaped electrode, the star-square electrode and the double side L-shaped electrodes. A comparison is presented at the end of the paper to highlight the advantages of each architecture
展开▼
机译:在本文中,对几种电极体系结构进行了建模,实施和比较,以优化芯片实验室(LoC)的混合微系统的集成。这项研究突出了混合和复杂微系统有限元模拟的局限性,并提出了一种新的方法来超越LoC设计中的某些制造约束条件。所提出的LoC基于介电电泳,用于细胞操作和电容感应架构。本研究中使用的颗粒直径小于10m,接近电极尺寸。在这种情况下,常规介电电泳理论有一些局限性。为了处理微米范围内的颗粒,我们描述了四种不同的电极结构,即尺寸为10m x 10m的常规正方形电极阵列,宽度为10m的L形电极,星形正方形电极和双面L-形电极。本文末尾进行了比较,以突出每种架构的优势
展开▼
