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Atmospheric Pressure Single Photon Laser Ionization (APSPLI) Mass Spectrometry Using a 157 Nm Fluorine Excimer Laser for Sensitive and Selective Detection of Non- to Semi-Polar Hydrocarbons

preprint
submitted on 10.11.2020, 14:17 and posted on 11.11.2020, 07:23 by Christopher Rüger, Anika Neumann, Martin Sklorz, Ralf Zimmermann
In this study, atmospheric pressure single photon ionization (APSPLI) mass spectrometry utilizing a fluorine excimer laser operated at 157 nm (7.9 eV) is presented for the first time. For evaluation and optimization, PAH standard mixtures introduced by gas chromatography were used. Atmospheric pressure laser ionization (APLI) approaches with laser wavelengths above 200 nm induce a multiphoton process, and ionization yields are strongly dependent on the heteroatom-content and isomeric structure. The presented technique using VUV photons allowed for the selective ionization of semi- to non-polar compounds in a single photon ionization process. Consequently, molecular radical cations were found as base peak, whereas protonated species were almost absent. Even though the ionization chamber is flushed by a high flow of pure nitrogen, remaining oxygen and water traces caused several side-reactions, leading to unwanted oxidized ionization artifacts. Installation of a water and oxygen filter cartridge significantly reduced the abundance of those artifacts, whereas the laser beam position was found to have a substantially lower effect. For evaluating complex mixture analysis, APSPLI was applied to characterize a light crude oil subjected to the ionization source by thermogravimetry and gas chromatography hyphenation. In addition to aromatic hydrocarbons, APSPLI also allowed for the sensitive ionization of sulfur-containing aromatic constituents, and even species with two sulfur-atoms could be detected. A comparison of APSPLI to APLI conducted at 266 nm revealed the additional compositional space accessible by the single photon process. This novel ionization concept is envisioned to have a high analytical potential further explored in the future.

Funding

Horizon 2020, Grant agreement ID: 731077

German Research Foundation (DFG), INST 264/56

History

Email Address of Submitting Author

christopher.rueger@uni-rostock.de

Institution

University of Rostock

Country

Germany

ORCID For Submitting Author

0000-0001-9634-9239

Declaration of Conflict of Interest

No conflict of interest.

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