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Abstract

High-temperature oxidations of hydrogen sulfide and methanethiol with O₂ and NO₂ were investigated using a special flow probe that was coupled to the ion-source housing of a high-resolution mass spectrometer. The direct coupling permitted prompt analysis of oxidation products effusing from the flow probe. Nominally isobaric ³²S–¹⁶O₂ doublets were resolved at a mass resolution of >8,000, which allowed for identification of several reaction products. Under conditions of medium-low pressure (0.8–4 Torr) and long mean residence times (0.5 s) in the probe, the oxidations yielded mostly stable products. Hydrogen sulfide was oxidized to form SO, SO₂, S₂ and S₂O whose relative intensities were studied as a function of temperature and reactant mixture composition. Methanethiol yielded CH₃SNO, CH₃SSCH₃, CS₂, SO₂ and traces of SO₃ and SO₃H depending on the temperature and reactant mixture composition.

Keywords

sulfur oxidaton combustion pyrolysis high-resolution mass spectrometry

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Study of Sulfur Oxidation Products by Pyrolysis High-Resolution Mass Spectrometry

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