Department of Chemistry, Indiana University, Bloomington, IN, 47405, USA.
J Am Soc Mass Spectrom. 2013 Dec;24(12):1853-61. doi: 10.1007/s13361-013-0723-9. Epub 2013 Oct 1.
Fundamental aspects of constant-momentum acceleration time-of-flight mass spectrometry (CMA-TOFMS) are explored as a means to improve mass resolution. By accelerating all ions to the same momentum rather than to the same energy, the effects of the initial ion spatial and energy distributions upon the total ion flight time are decoupled. This decoupling permits the initial spatial distribution of ions in the acceleration region to be optimized independently, and energy focus, including ion turn-around-time error, to be accomplished with a linear-field reflectron. Constant-momentum acceleration also linearly disperses ions across time according to mass-to-charge (m/z) ratio, instead of the quadratic relationship between flight time and m/z found in conventional TOFMS. Here, CMA-TOFMS is shown to achieve simultaneous spatial and energy focusing over a selected portion of the mass spectrum. An orthogonal-acceleration time-of-flight system outfitted with a reduced-pressure DC glow discharge (GD) ionization source is used to demonstrate CMA-TOFMS with atomic ions. The influence of experimental parameters such as the amplitude and width of the time-dependent CMA pulse on mass resolution is investigated, and a useful CMA-TOFMS focusing window of 2 to 18 Da is found for GD-CMA-TOFMS.
恒定动量加速飞行时间质谱(CMA-TOFMS)的基本原理,可作为提高质量分辨率的一种手段。通过将所有离子加速到相同的动量,而不是相同的能量,初始离子空间和能量分布对总离子飞行时间的影响就被解耦。这种解耦允许在加速区域中独立地优化离子的初始空间分布,并通过线性场反射器来实现能量聚焦,包括离子回转时间误差。恒定动量加速还根据质荷比(m/z)线性地在时间上离散离子,而不是传统飞行时间质谱中飞行时间与 m/z 之间的二次关系。这里,CMA-TOFMS 被证明可以在质谱的选定部分同时实现空间和能量聚焦。配备低压直流辉光放电(GD)电离源的正交加速飞行时间系统用于用原子离子演示 CMA-TOFMS。研究了实验参数(如时变 CMA 脉冲的幅度和宽度)对质量分辨率的影响,发现 GD-CMA-TOFMS 的有用 CMA-TOFMS 聚焦窗口为 2 到 18 Da。
