Fundamental considerations for the application of miniature Ion mobility spectrometry to field analytical applications

Field Analytical Chemistry and Technology Pub Date : 2000-01-01 DOI:10.1002/1520-6521(2000)4:5<255::AID-FACT5>3.0.CO;2-R

G. Spangler

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引用次数: 18

Abstract

Ion mobility spectrometry (IMS) is a popular field analyzer. The reason for its popularity is its small size, its sensitivity, and the amount of information contained in the ion mobility spectrum. Several research groups are working on smaller IMS cells using microelectromechanical systems (MEMS) technology. New principles of operation will be needed to achieve this goal. The theory supporting the development of the radio frequency (RF) IMS is described. RF-IMS separates ions by applying an asymmetric RF field across two parallel plates and passing the ions through the separator. The performance of the device no longer depends on a simple linear relationship between the drift velocity and an electric field, but rather on a nonlinear relationship between these parameters. Consequently, a more detailed momentum-transfer theory is needed. The required theory is developed and applied to the interpretation of experimental data here. The importance of using momentum transfer theory in combination with the continuity equation is demonstrated. © 2000 John Wiley & Sons, Inc. Field Analyt Chem Technol 4: 255–267, 2000

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微型离子迁移率光谱法应用于现场分析的基本考虑

离子迁移谱法(IMS)是一种流行的现场分析仪。它受欢迎的原因是它的体积小，灵敏度高，离子迁移谱中包含的信息量大。几个研究小组正在使用微机电系统(MEMS)技术研究更小的IMS单元。要实现这一目标，需要新的操作原则。介绍了支持射频(RF) IMS发展的理论。RF- ims通过在两个平行板上施加不对称射频场并使离子通过分离器来分离离子。器件的性能不再依赖于漂移速度和电场之间的简单线性关系，而是依赖于这些参数之间的非线性关系。因此，需要一个更详细的动量传递理论。所需的理论在这里得到发展并应用于实验数据的解释。论证了动量传递理论与连续性方程相结合的重要性。©2000 John Wiley & Sons, Inc化学工程学报(英文版)，2000

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Field Analytical Chemistry and Technology

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