Detailed Comparison of Xenon APPI (9.6/8.4 eV), Krypton APPI (10.6/10.0 eV), APCI, and APLI (266 nm) for Gas Chromatography High Resolution Mass Spectrometry of Standards and Complex Mixtures

Abstract: Photoionization schemes for mass spectrometry, either by laser or discharge lamps, have been widely examined and deployed. In this work, the ionization characteristics of a xenon discharge lamp (Xe-APPI, 9.6/8.4 eV) have been studied and compared to established ionization schemes, such as atmospheric pressure chemical ionization, atmospheric pressure photoionization with a krypton discharge lamp (Kr-APPI, 10.6/10 eV) and atmospheric pressure laser ionization (266 nm). Addressing the gas-phase ionization behavi… Show more

“…The CH class shows, regardless of the peat origin and for both combustion conditions, an intensity maximum at 27–31 carbons and DBE values between 6 and 10. In the literature, a variety of different organic compounds was identified in peat that includes n -alkanes, fatty acids, alcohols, and squalene as well as cyclic compounds such as di- and triterpenoids or steroids. , However, the here observed DBE/#C range fit especially squalene (C 30 H 50 , DBE 6) and its derivatives or sterane-based biomarkers, which can also be ionized by APPI …”

“…Smoldering combustion is known to emit nitrogen-containing compounds from the low-temperature, oxygen-depleted combustion of biomass, and in particular, peat was found to emit high concentrations of, e.g., pyridine-like compounds, which would fit the observed distribution in the DBE versus carbon number plot (Figure b) . The overall number and intensity of nitrogen-containing compounds is low compared to the other classes, which may partially be explained by their lower ionization efficiency in APPI. , …”

Accessing the Low-Polar Molecular Composition of Boreal and Arctic Peat-Burning Organic Aerosol via Thermal Analysis and Ultrahigh-Resolution Mass Spectrometry: Structural Motifs and Their Formation

“…The CH class shows, regardless of the peat origin and for both combustion conditions, an intensity maximum at 27–31 carbons and DBE values between 6 and 10. In the literature, a variety of different organic compounds was identified in peat that includes n -alkanes, fatty acids, alcohols, and squalene as well as cyclic compounds such as di- and triterpenoids or steroids. , However, the here observed DBE/#C range fit especially squalene (C 30 H 50 , DBE 6) and its derivatives or sterane-based biomarkers, which can also be ionized by APPI …”

“…Smoldering combustion is known to emit nitrogen-containing compounds from the low-temperature, oxygen-depleted combustion of biomass, and in particular, peat was found to emit high concentrations of, e.g., pyridine-like compounds, which would fit the observed distribution in the DBE versus carbon number plot (Figure b) . The overall number and intensity of nitrogen-containing compounds is low compared to the other classes, which may partially be explained by their lower ionization efficiency in APPI. , …”

Accessing the Low-Polar Molecular Composition of Boreal and Arctic Peat-Burning Organic Aerosol via Thermal Analysis and Ultrahigh-Resolution Mass Spectrometry: Structural Motifs and Their Formation

“…TENG ion sources use low-voltage power supplies to drive the necessary mechanical motion, with the generated high-voltage electricity presenting little more danger than static shock. As compared to other liquid ionization techniques which also do not require high-voltage power supplies such as atmospheric-pressure photoionization, vibrating sharp-edge spray ionization, and zero-voltage paperspray, TENG is unique in that it can preserve the high sensitivity and other traits associated with nESI when used with standard glass capillary nESI emitters. ,− …”

Triboelectric Nanogenerators for the Masses: A Low-Cost Do-It-Yourself Pulsed Ion Source for Sample-Limited Applications

“…24,32,33 To overcome these disadvantages, atmospheric pressure photoionization (APPI) could be used. 34…”

GC-FTICR mass spectrometry with dopant assisted atmospheric pressure photoionization: application to the characterization of plastic pyrolysis oil