双极性离子限制与迁移率分离

Dual Polarity Ion Confinement and Mobility Separations.

作者信息

Attah Isaac K, Garimella Sandilya V B, Webb Ian K, Nagy Gabe, Norheim Randolph V, Schimelfenig Colby E, Ibrahim Yehia M, Smith Richard D

机构信息

Biological Sciences Division, Pacific Northwest National Laboratory, Richland, WA, USA.

出版信息

J Am Soc Mass Spectrom. 2019 Jun;30(6):967-976. doi: 10.1007/s13361-019-02138-1. Epub 2019 Mar 4.

DOI:10.1007/s13361-019-02138-1

PMID:30834510

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6520127/

Abstract

Here, we present simulations and describe the initial implementation of a device capable of performing simultaneous ion mobility (IM) separations of positive and negative ions based upon the structures for lossless ion manipulations (SLIM). To achieve dual polarity ion confinement, the DC fields used for lateral confinement in previous SLIM were replaced with RF fields. Concurrent ion transport and mobility separation in the SLIM device are shown possible due to the nature of the traveling wave (TW) voltage profile which has potential minima at opposite sides of the wave for each ion polarity. We explored the potential for performing simultaneous IM separations of cations and anions over the same SLIM path and the impacts on the achievable IM resolution and resolving power. Initial results suggest comparable IM performance with previous single-polarity SLIM separations can be achieved. We also used ion trajectory simulations to investigate the capability to manipulate the spatial distributions of ion populations based on their polarities by biasing the RF fields and TW potentials on each SLIM surface so as to limit the interactions between opposite polarity ions. Graphical Abstract.

摘要

在此，我们展示了模拟结果，并描述了一种基于无损离子操纵结构（SLIM）能够同时对正离子和负离子进行离子迁移率（IM）分离的设备的初步实现。为实现双极性离子限制，先前SLIM中用于横向限制的直流电场被射频电场取代。由于行波（TW）电压分布的特性，即对于每种离子极性在波的相对两侧具有电势最小值，因此在SLIM设备中同时进行离子传输和迁移率分离是可行的。我们探索了在同一SLIM路径上同时对阳离子和阴离子进行IM分离的潜力，以及对可实现的IM分辨率和分辨能力的影响。初步结果表明，可实现与先前单极性SLIM分离相当的IM性能。我们还使用离子轨迹模拟来研究通过在每个SLIM表面上对射频电场和TW电势施加偏置，基于离子极性操纵离子群体空间分布的能力，以限制相反极性离子之间的相互作用。图形摘要。

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