Simulation study of a planar quadrupole mass filter for MEMS mass spectrometer

IF 1.2 4区 化学 Q4 CHEMISTRY, ANALYTICAL
Yu-Peng CHENG , Chen SHEN , Zhang-Xu WU , Shan LI , You-Jiang LIU , Han WANG , Chi-Lai CHEN
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引用次数: 0

Abstract

Micro-electro-mechanical system (MEMS) based mass spectrometry, MEMS mass spectrometry, emerges a new technique branch of miniature mass spectrometry. One of the main challenges hindering the development of MEMS mass spectrometry is the poor compatibility between the complex electrode structure of traditional ion optics and MEMS processes. This paper proposed a planar quadrupole mass filter utilizing a highly simplified stacked-layer structure and film electrodes, which is easy to fabricate with high precision by MEMS surface micromachining. The ion trajectory simulation model of the MEMS mass spectrometry chip involving all necessary ion optics was elaborated for investigating the preliminary performance of the planar quadrupole mass filter. By optimizing the crucial parameters such as the frequency of radio frequency voltage, the ratio of direct current voltage and radio frequency voltage, pre-pole length, main-pole length, and injection kinetic energy, the preliminary simulation result of planar quadrupole mass filter achieved a 1–2 Da peak width (at 50% of peak height) and 20–80% ion transmission efficiency. Importantly, the planar quadrupole mass filter demonstrated a maximum working pressure of 0.1 Pa (using air as the buffer gas), 100 times higher than that of conventional quadrupole mass filters, while maintaining a 0.7–1.8 Da peak width and ∼5% ion transmission efficiency. Additionally, to modify the theoretical formulas for the non-ideal quadrupolar field of planar quadrupole mass filter, a novel approach based on stability diagrams obtained by simulation was also introduced. The pretty good linearity (R2=1) between ion masses in the range of 10 to 100 Da and the corresponding radio frequency voltages was verified through the simulated mass spectra. Notably, the proportional coefficient of ion mass and radio frequency voltage exhibited a minimal 4% deviation between the simulated value (4.7132 V0P/Da) and the calculated value (4.9036 V0P/Da) through the modified formula. In conclusion, the preliminary simulation results demonstrated that the planar quadrupole mass filter possessed moderate performance, high-pressure tolerance, and excellent theoretical consistency, which proved it a promising technology of MEMS mass spectrometry. It can find applications in the fields of gas detection, including the rapid response to hazardous gas emissions and in situ detection of dissolved gases in the deep sea.

Abstract Image

Abstract Image

用于 MEMS 质谱仪的平面四极杆质量过滤器的仿真研究
基于微机电系统(MEMS)的质谱法(MEMS 质谱法)是微型质谱法的一个新技术分支。传统离子光学的复杂电极结构与 MEMS 工艺的兼容性差是阻碍 MEMS 质谱发展的主要挑战之一。本文提出了一种平面四极杆质量滤波器,利用高度简化的叠层结构和薄膜电极,易于通过 MEMS 表面微加工实现高精度制造。为了研究平面四极质谱滤波器的初步性能,我们建立了 MEMS 质谱芯片的离子轨迹仿真模型,其中包括所有必要的离子光学器件。通过优化射频电压频率、直流电压与射频电压的比例、前极长度、主极长度和注入动能等关键参数,平面四极杆质量滤波器的初步模拟结果达到了 1∼2Da 的峰宽(峰高的 50%)和 20∼80% 的离子传输效率。重要的是,平面四极杆质量过滤器的最大工作压力为 0.1 Pa(使用空气作为缓冲气体),是传统四极杆质量过滤器的 100 倍,同时保持了 0.7∼1.8 Da 的峰宽和 ∼5% 的离子传输效率。此外,为了修改平面四极质量滤波器非理想四极场的理论公式,还引入了一种基于模拟获得的稳定性图的新方法。通过模拟质谱验证了 10 至 100Da 范围内的离子质量与相应射频电压之间具有相当好的线性关系(R2=1)。值得注意的是,离子质量和射频电压的比例系数在模拟值(4.7132 V0P/Da)和修改公式后的计算值(4.9036 V0P/Da)之间的偏差极小,仅为 4%。总之,初步模拟结果表明,平面四极杆质量滤波器具有适中的性能、高压耐受性和良好的理论一致性,证明它是一种很有前途的 MEMS 质谱技术。它可应用于气体检测领域,包括危险气体排放的快速反应和深海溶解气体的原位检测。
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
CiteScore
3.60
自引率
25.00%
发文量
17223
审稿时长
35 days
期刊介绍: Chinese Journal of Analytical Chemistry(CJAC) is an academic journal of analytical chemistry established in 1972 and sponsored by the Chinese Chemical Society and Changchun Institute of Applied Chemistry, Chinese Academy of Sciences. Its objectives are to report the original scientific research achievements and review the recent development of analytical chemistry in all areas. The journal sets up 5 columns including Research Papers, Research Notes, Experimental Technique and Instrument, Review and Progress and Summary Accounts. The journal published monthly in Chinese language. A detailed abstract, keywords and the titles of figures and tables are provided in English, except column of Summary Accounts. Prof. Wang Erkang, an outstanding analytical chemist, academician of Chinese Academy of Sciences & Third World Academy of Sciences, holds the post of the Editor-in-chief.
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