Ionization of semi-fluorinated n-alkanes in controlled atmosphere using flexible micro-tube plasma (FμTP) ionization source with square- and sine-wave voltage

Non-thermal plasma-based ionization sources have been widely used and shown excellent soft ionization performance in mass spectrometry. Despite their extensive application, the ionization mechanisms of these sources are of great interest for further exploring their full potential. A controlled atmosphere can provide a clean and controllable ionization environment and is beneficial for studying the ionization mechanism. The plasma source itself also has a significant impact on the ionization mechanism of the analyte, and the voltage waveform is one of the key parameters for controlling the plasma source. In this paper, a miniature flexible micro-tube plasma (F mu TP) ionization source was sustained using both square and sine-wave voltage. The ionization processes of typical semi-fluorinated n-alkanes (SFAs) were investigated in the controlled atmosphere filled with 80% N-2 and 20% O-2. The main mass peaks using both square and sine-wave voltages are found to be [M-mH](+) and [MmH+nO](+) (m = 1, 3; n = 0, 1, 2). However, for the square-wave voltage, the [M-H+O](+) species are the most abundant while [M-H](+) species are dominant for the sine-wave voltage, showing that the plasma generated with sine-wave voltage is somewhat softer than the one with square-wave voltage for SFAs. With the assistance of optical spectroscopy, the plasma developments in one discharge cycle for both voltage waveforms were obtained. Only one discharge can be found in each half cycle for square-wave voltage while several for the sine wave voltage. These would be responsible for the different ionization behaviors in these two cases. This work provides more insight into the ionization mechanism of SFAs and more understanding of plasma-based soft ionization. In addition, the analytical performance was evaluated to be comparable when using these two voltage generators with a big difference in cost, which will benefit the instrumental development.

Automated summary

This study investigated the ionization mechanism of SFAs by controlling the atmosphere and using square and sine-wave voltage to generate plasma. It revealed the differences in ionization effects on SFAs of plasma generated by different voltage waveforms, providing more understanding of plasma-based soft ionization. Additionally, optical spectroscopy was used to analyze the plasma development in one discharge cycle under different voltage waveforms.