2020
DOI: 10.1021/acs.analchem.0c00681
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Fragmentation of Saturated Hydrocarbons upon Atmospheric Pressure Chemical Ionization Is Caused by Proton-Transfer Reactions

Abstract: Chemical characterization of complex mixtures of large saturated hydrocarbons is critically important for numerous fields, including petroleomics and renewable transportation fuels, but difficult to achieve. Atmospheric pressure chemical ionization (APCI) mass spectrometry has shown some promise in the analysis of saturated hydrocarbons. However, APCI causes extensive fragmentation to these compounds, which impedes its effectiveness. To prevent this fragmentation, its causes were examined via gas-phase ion−mol… Show more

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Cited by 24 publications
(36 citation statements)
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“…The nature of the species responsible for hydride abstraction or protonation and subsequent hydrogen elimination in the first step is still unclear; therefore, only the following steps are presented in detail. The existence of several reactive species like H 3 O + , ozone, O 2 + , N 2 + , or nitrogen oxides, some of them capable of hydride abstraction and dehydrogenation, is known for nitrogen DBDI and related ion sources. ,,, The theory of hydride abstraction is further supported by [M–H] + and [M–3H] + signals, which are observable for small alkanes. The addition of water and subsequent dehydrogenation with the loss of one hydrogen from the alkane and one hydrogen from water is proposed as the mechanism explaining the resulting pattern of the isotope labeling experiments.…”
Section: Resultsmentioning
confidence: 99%
“…The nature of the species responsible for hydride abstraction or protonation and subsequent hydrogen elimination in the first step is still unclear; therefore, only the following steps are presented in detail. The existence of several reactive species like H 3 O + , ozone, O 2 + , N 2 + , or nitrogen oxides, some of them capable of hydride abstraction and dehydrogenation, is known for nitrogen DBDI and related ion sources. ,,, The theory of hydride abstraction is further supported by [M–H] + and [M–3H] + signals, which are observable for small alkanes. The addition of water and subsequent dehydrogenation with the loss of one hydrogen from the alkane and one hydrogen from water is proposed as the mechanism explaining the resulting pattern of the isotope labeling experiments.…”
Section: Resultsmentioning
confidence: 99%
“…The ionization mechanism of APCI for other compounds has been studied previously. Referring to the ionization process reported in other literature, we propose the ionization mechanisms for thiophene compounds in this work (shown in the Supporting Information). [M] +• and [M + H] + could be generated through charge exchange and proton transfer, respectively.…”
Section: Resultsmentioning
confidence: 99%
“…The proton affinity of formaldehyde (712.9 kJ/mol) is only 22 kJ/mol higher than the proton affinity of water. Therefore, the formaldehyde signal depends on the humidity [72]), in contrast to most other species detected with PTRMS [73][74][75][76]. A formaldehyde calibration based on two parameters (the formaldehyde sensitivity and the humidity) was performed, arriving at the values we have reported.…”
Section: Formaldehyde Calibrationmentioning
confidence: 99%