Simulation study of digital waveform‐driven quadrupole mass filter operated in higher stability regions for high‐resolution inductively coupled plasma mass spectrometry

Abstract

RationaleThe use of a frequency‐scanned digital quadrupole mass filter (QMF) with varying duty cycles shows promise for application as a high‐resolution mass analyzer design for inductively coupled plasma mass spectrometry (ICP‐MS). High resolution in ICP‐MS is important to overcome isobaric polyatomic interferences. Here, we explore the possibility and the characteristics of using a digital quadrupole operating in higher stability regions for ICP‐MS.MethodsWe perform computational simulations in SIMION of a digital QMF that is operated by scanning the frequency of the digital waveform at a fixed driving voltage and various duty cycles. For ions in the atomic mass range (7–238 m/z), we investigate the expected resolution, transmission, fringe field effects, and ion trajectories. We compare different characteristics between sine and digital waveform QMF.ResultsWithin the capability of current digital waveform generation technology, a digital QMF can produce variable mass resolution, from several hundred to more than 10 000. This mass resolution covers the low, medium, and high resolutions that are typical for sector‐field ICP‐MS. Additionally, simulations suggest that transmission of the QMF remains high at high resolution. For example, with 87.50/12.50 duty cycle (zone 4,1), resolution at 10% peak width is 10 420 for m/z 80. The transmission through the quadrupole, which is constant for all isoenergetic ions, is ~2.5%, and most ion loss is due to the defocusing effects of the fringe field. Compared to sinusoidal QMFs, ions need many fewer cycles in the digital QMF to obtain high resolution.ConclusionThe results demonstrate that the use of a frequency‐scanned, duty‐cycle‐modulated digital QMF as the mass analyzer for ICP‐MS has the potential to produce high resolution while maintaining considerable transmission, thus overcoming most spectral interferences in elemental MS.