Department of Chemistry, Indiana University, Bloomington, Indiana 47405, United States.
Anal Chem. 2013 Aug 6;85(15):7512-8. doi: 10.1021/ac401524x. Epub 2013 Jul 15.
The flowing atmospheric-pressure afterglow (FAPA) is a promising new source for atmospheric-pressure, ambient desorption/ionization mass spectrometry. However, problems exist with reproducible sample introduction into the FAPA source. To overcome this limitation, a new FAPA geometry has been developed in which concentric tubular electrodes are utilized to form a halo-shaped discharge; this geometry has been termed the halo-FAPA or h-FAPA. With this new geometry, it is still possible to achieve direct desorption and ionization from a surface; however, sample introduction through the inner capillary is also possible and improves interaction between the sample material (solution, vapor, or aerosol) and the plasma to promote desorption and ionization. The h-FAPA operates with a helium gas flow of 0.60 L/min outer, 0.30 L/min inner, and applied current of 30 mA at 200 V for 6 W of power. In addition, separation of the discharge proper and sample material prevents perturbations to the plasma. Optical-emission characterization and gas rotational temperatures reveal that the temperature of the discharge is not significantly affected (<3% change at 450 K) by water vapor during solution-aerosol sample introduction. The primary mass-spectral background species are protonated water clusters, and the primary analyte ions are protonated molecular ions (M + H(+)). Flexibility of the new ambient sampling source is demonstrated by coupling it with a laser ablation unit, a concentric nebulizer, and a droplet-on-demand system for sample introduction. A novel arrangement is also presented in which the central channel of the h-FAPA is used as the inlet to a mass spectrometer.
流动大气压后辉光(FAPA)是一种有前途的大气压、环境解吸/电离质谱新源。然而,在可重复引入样品进入 FAPA 源方面存在问题。为了克服这一限制,开发了一种新的 FAPA 几何形状,其中同心管状电极用于形成晕状放电;这种几何形状被称为晕环 FAPA 或 h-FAPA。利用这种新的几何形状,仍然可以实现从表面直接解吸和电离;然而,通过内毛细管引入样品也是可能的,并且可以改善样品材料(溶液、蒸气或气溶胶)与等离子体之间的相互作用,以促进解吸和电离。h-FAPA 在 200 V 时以 0.60 L/min 外、0.30 L/min 内的氦气流和 30 mA 的电流运行,功率为 6 W。此外,将放电本身与样品材料分离可防止对等离子体的干扰。光发射特性和气体转动温度表明,在溶液-气溶胶样品引入过程中,水蒸气对放电温度的影响不大(在 450 K 时变化小于 3%)。主要的质谱背景物质是质子化水团簇,主要的分析物离子是质子化分子离子(M+H(+))。通过将其与激光烧蚀单元、同心雾化器和按需滴液系统耦合,展示了新的环境采样源的灵活性,用于样品引入。还提出了一种新颖的布置,其中 h-FAPA 的中心通道用作质谱仪的入口。