Dielectrophoretic Devices Fabricated by Proton Beam Writing for Concentration, Assembly, and Detection of Nanoparticles

2020 International Symposium on Electrical Insulating Materials (ISEIM) Pub Date : 2020-09-13 DOI:10.1541/ieejfms.141.574

Toshiki Kimura, Ryousuke Kawashima, Ken Yamamoto, S. Uchida, Y. Ishii, H. Nishikawa

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Abstract

Dielectrophoresis (DEP) is a phenomenon with directional movement of micro particles due to the DEP force under uneven AC electric field. We utilize polymer surface with microstructures such as μm-scale pit arrays for DEP devices to assemble or concentrate nanoparticles. For micro-structuring of the polymer such as PMMA with thickness of 5–10 μm, we applied proton beam writing (PBW) which is a direct-write lithographic technique for high-aspect ratio microstructures of polymeric materials such as PMMA and epoxy resin. Pit arrays such as 5 x 5 arrays of circular pits with diameter of 5 μm on the 5–10 μm thick PMMA. We were able to demonstrate collection and assembly of gold and Ag nanoparticles (diameter of 100 to 250 nm) on the PMMA pit arrays from the colloidal suspension of the metallic nanoparticles in water. The DEP experiments were performed with the amplitude (10–20 V) and frequency (1–100 kHz) of applied ac voltages with additional dc offset voltage of less than 1V. We also discuss possible application of this technique to the detection of micro and nanoparticles such as plastics, dielectrics and metals in environmental water.

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质子束写入制备用于纳米颗粒浓缩、组装和检测的介电装置

介质电泳(DEP)是在不均匀的交流电场作用下，由于DEP力的作用，微粒子发生定向运动的现象。我们利用具有微米级凹坑阵列等微结构的聚合物表面用于DEP器件组装或浓缩纳米粒子。对于厚度为5-10 μm的聚合物(如PMMA)的微结构，我们采用了质子束刻写(PBW)技术，这是一种用于PMMA和环氧树脂等聚合物材料的高纵横比微结构的直写光刻技术。凹坑阵列，如5 × 5直径为5 μm的圆形凹坑阵列，在5 ~ 10 μm厚的PMMA上。我们能够演示金纳米粒子和银纳米粒子(直径为100到250纳米)在PMMA坑阵列上的收集和组装，这些纳米粒子来自于水中的金属纳米粒子的胶体悬浮液。DEP实验在施加交流电压的幅度(10-20 V)和频率(1-100 kHz)下进行，外加直流偏置电压小于1V。我们还讨论了该技术在环境水中塑料、电介质和金属等微粒子和纳米粒子检测中的应用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2020 International Symposium on Electrical Insulating Materials (ISEIM)

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