Subtractive Microfluidics in CMOS.

Technical digest. International Electron Devices Meeting Pub Date : 2024-12-01 DOI:10.1109/iedm50854.2024.10873317

Wei-Yang Weng, Alexander Di, Xiang Zhang, Ya-Chen Tsai, Yan-Ting Hsiao, Jun-Chau Chien

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Abstract

This paper introduces a microfluidics platform embedded within a silicon chip implemented in CMOS technology. The platform utilizes a one-step wet etching method to create fluidic channels by selectively removing CMOS back-end-of-line (BEOL) routing metals. We term our technique "subtractive" microfluidics, to complement those fabricated with additive manufacturing. Three types of structures are presented in a TSMC 180-nm CMOS chip: (1) passive microfluidics in the form of a micro-mixer and a 1:64 splitter, (2) fluidic channels with embedded ion-sensitive field-effect transistors (ISFETs) and Hall sensors, and (3) integrated on-chip impedance-sensing readout circuits including voltage drivers and a fully differential transimpedance amplifier (TIA). Sensors and transistors are functional pre- and post-etching with minimal changes in performance. Our CMOS subtractive microfluidics technique enables tight integration of fluidics and electronics, paving the way for future small-size, high-throughput lab-on-chip (LOC) devices.

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CMOS中的减法微流控。

介绍了一种基于CMOS技术的嵌入式硅芯片微流控平台。该平台采用一步湿法蚀刻方法，通过选择性去除CMOS后端线（BEOL）布线金属来创建流体通道。我们将我们的技术称为“减法”微流体，以补充那些用增材制造制造的技术。在台积电180纳米CMOS芯片上提出了三种结构：(1)以微混频器和1:64分频器形式的无源微流体，(2)嵌入离子敏感场效应晶体管（isfet）和霍尔传感器的流体通道，以及(3)集成的片上阻抗传感读出电路，包括电压驱动器和全差分跨阻放大器（TIA）。传感器和晶体管在蚀刻前和蚀刻后都是功能性的，性能变化很小。我们的CMOS减法微流控技术实现了流体学和电子学的紧密集成，为未来的小尺寸、高通量芯片实验室（LOC）设备铺平了道路。

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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来源期刊

Technical digest. International Electron Devices Meeting

CiteScore

4.50

自引率

0.00%

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