Revealing the Ion Chemistry Occurring in High Kinetic Energy-Ion Mobility Spectrometry: A Proof of Principle Study

Analytica Pub Date : 2023-04-23 DOI:10.3390/analytica4020010

Florentin Weiss, C. Schaefer, S. Zimmermann, T. Märk, C. Mayhew

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Abstract

Here, we present proof of principle studies to demonstrate how the product ions associated with the ion mobility peaks obtained from a High Kinetic Energy-Ion Mobility Spectrometer (HiKE-IMS) measurement of a volatile can be identified using a Proton Transfer Reaction/Selective Reagent Ion-Time-of-Flight-Mass Spectrometer (PTR/SRI-ToF-MS) when operating both instruments at the same reduced electric field value and similar humidities. This identification of product ions improves our understanding of the ion chemistry occurring in the ion source region of a HiKE-IMS. The combination of the two analytical techniques is needed, because in the HiKE-IMS three reagent ions (NO+, H3O+ and O2+•) are present at the same time in high concentrations in the reaction region of the instrument for reduced electric fields of 100 Td and above. This means that even with a mass spectrometer coupled to the HiKE-IMS, the assignment of the product ions to a given reagent ion to a high level of confidence can be challenging. In this paper, we demonstrate an alternative approach using PTR/SRI-ToF-MS that allows separate investigations of the reactions of the reagent ions NO+, H3O+ and O2+•. In this study, we apply this approach to four nitrile containing organic compounds, namely acetonitrile, 2-furonitrile, benzonitrile and acrylonitrile. Both the HiKE-IMS and the PTR/SRI-ToF-MS instruments were operated at a commonly used reduced electric field strength of 120 Td and with gas flows at the same humidities.

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揭示高能离子迁移率光谱中发生的离子化学:一个原理研究的证明

在这里，我们提出了原理研究的证明，以证明如何使用质子转移反应/选择性试剂离子飞行时间质谱仪(PTR/SRI-ToF-MS)在相同的电场值和相似的湿度下操作两种仪器时，与挥发性物的高动能离子迁移谱仪(HiKE-IMS)测量获得的离子迁移峰相关的产物离子可以被识别。这种对产物离子的鉴定提高了我们对HiKE-IMS离子源区域发生的离子化学的理解。需要两种分析技术的结合，因为在HiKE-IMS中，在100 Td及以上的还原电场中，三种试剂离子(NO+， h30 +和O2+•)同时以高浓度存在于仪器的反应区。这意味着，即使使用与HiKE-IMS耦合的质谱仪，将产物离子分配到给定的试剂离子的高可信度也是具有挑战性的。在本文中，我们展示了一种使用PTR/SRI-ToF-MS的替代方法，该方法允许对试剂离子NO+， h30 +和O2+•的反应进行单独的研究。在本研究中，我们将这种方法应用于四种含腈的有机化合物，即乙腈、2-呋喃腈、苯腈和丙烯腈。HiKE-IMS和PTR/SRI-ToF-MS仪器都在120 Td的常用电场强度和相同湿度的气流下工作。

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

Analytica

CiteScore

1.80

自引率

0.00%

发文量