In-Situ Monitoring of Gas Molecules in Chromatography by Utilizing a Pressure Sensor

2020 IEEE 33rd International Conference on Micro Electro Mechanical Systems (MEMS) Pub Date : 2020-01-01 DOI:10.1109/MEMS46641.2020.9056336

A. Bulbul, Hanseup Kim

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引用次数: 1

Abstract

We report a novel concept and testing results of utilizing a pressure sensor as an in-situ gas sensor for a micro gas chromatography system. The pressure sensor utilized a phenomenon that instant viscosity variation by an injection of gas molecules into a background gas stream caused instant pressure transient thus making it feasible to the in-situ monitor gas molecules using a pressure sensor during gas chromatography operation. Such a concept of viscosity-to-pressure conversion was experimentally proven and implemented. The implemented pressure sensors at multiple locations successfully monitored the progress of gas molecules in separation in four serially connected micro columns. This pressure sensor based chromatogram generated 125.5 Pa of pressure for $0.5\ \mu\mathrm{L}$ of hexane sample and showed a separation of hexane and heptane mixture with plate numbers of 93.68 and 244.69 respectively and with a separation distance and resolution of 30.5 and 2.4 respectively. The separation distance and resolution were 0.86 and 1.45 times to that of in FID separation, indicating no significant pressure sensor influences on separation.

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利用压力传感器对色谱中气体分子进行原位监测

我们报告了一种利用压力传感器作为微气相色谱系统的原位气体传感器的新概念和测试结果。该压力传感器利用了一种现象，即通过向背景气流中注入气体分子而导致瞬时粘度变化，从而导致瞬时压力瞬变，从而使在气相色谱操作过程中使用压力传感器对气体分子进行现场监测成为可能。这种粘度-压力转换的概念在实验中得到了验证和实现。安装在多个位置的压力传感器成功地监测了气体分子在四个串联微柱中的分离过程。该压力传感器色谱图对$0.5\ \mu\ mathm {L}$的正己烷样品产生125.5 Pa的压力，分离出正己烷和正庚烷混合物，板数分别为93.68和244.69，分离距离和分辨率分别为30.5和2.4。分离距离和分辨率分别是FID分离的0.86倍和1.45倍，表明压力传感器对分离无显著影响。

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2020 IEEE 33rd International Conference on Micro Electro Mechanical Systems (MEMS)

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