Encoded Frequent Pushing - Improving Duty Cycle in the Folded Flight Path High Resolution Time-of-Flight Mass Spectrometry
Technical notes | 2018 | LECOInstrumentation
The duty cycle of orthogonal-acceleration time-of-flight mass spectrometers (OA-TOFMS) directly impacts sensitivity by determining the fraction of generated ions that reach the analyzer. In high-resolution folded flight path (FFP) analyzers, extended flight times improve resolving power but reduce duty cycle and thus sensitivity. Encoded Frequent Pushing (EFP) addresses this trade-off by increasing ion sampling efficiency without compromising resolution or mass range.
This work presents the development and application of EFP in a multi-reflecting FFP TOFMS to enhance duty cycle, sensitivity, dynamic range, and mass accuracy during GC-HRT and GCxGC-HRT analyses. Key goals include evaluating sensitivity gains, dynamic range extension, noise reduction, and mass accuracy improvements.
EFP employs a unique sequence of multiple accelerator push pulses within each transient, with non-uniform time intervals to avoid systematic spectral overlaps. A logical and statistical decoding algorithm, executed in real time, aligns ion signals from each push according to known timing (e.g., Ti=TD·i·(i–1)/2) and reconstructs de-multiplexed spectra without introducing artifacts typical of Hadamard transforms.
EFP enables higher throughput and sensitivity in environmental, forensic, and industrial QA/QC workflows by detecting lower concentration compounds without extending analysis time. The method integrates seamlessly with existing GC-HRT and GCxGC-HRT platforms, improving trace analysis, isotope ratio measurements, and high-speed separations.
Further innovations may include adaptive encoding schemes tailored to sample complexity, integration with alternative ionization sources (e.g., APCI, MALDI), and real-time feedback loops for dynamic interval adjustment. EFP could be extended to other MR-TOF configurations and combined with machine-learning-based decoding to handle highly populated spectra.
Encoded Frequent Pushing significantly enhances the duty cycle and analytical performance of FFP high-resolution TOFMS by multiplexing ion extraction with unique timing and artifact-free decoding. The approach delivers up to tenfold sensitivity gains, extended dynamic range, full mass range operation, noise suppression, and improved mass accuracy, broadening the applicability of GC-HRT and GCxGC-HRT techniques.
GC/MSD, GC/HRMS, GC/TOF
IndustriesManufacturerLECO
Summary
Significance of the Topic
The duty cycle of orthogonal-acceleration time-of-flight mass spectrometers (OA-TOFMS) directly impacts sensitivity by determining the fraction of generated ions that reach the analyzer. In high-resolution folded flight path (FFP) analyzers, extended flight times improve resolving power but reduce duty cycle and thus sensitivity. Encoded Frequent Pushing (EFP) addresses this trade-off by increasing ion sampling efficiency without compromising resolution or mass range.
Objectives and Overview of the Study
This work presents the development and application of EFP in a multi-reflecting FFP TOFMS to enhance duty cycle, sensitivity, dynamic range, and mass accuracy during GC-HRT and GCxGC-HRT analyses. Key goals include evaluating sensitivity gains, dynamic range extension, noise reduction, and mass accuracy improvements.
Used Instrumentation
- LECO Pegasus GC-HRT high-resolution TOF mass spectrometer with FFP analyzer
- Orthogonal accelerator pulser operating at 2 kHz (standard) and up to 20 kHz (EFP mode)
- Electron impact ion source coupled to GC or GCxGC systems
Methodology
EFP employs a unique sequence of multiple accelerator push pulses within each transient, with non-uniform time intervals to avoid systematic spectral overlaps. A logical and statistical decoding algorithm, executed in real time, aligns ion signals from each push according to known timing (e.g., Ti=TD·i·(i–1)/2) and reconstructs de-multiplexed spectra without introducing artifacts typical of Hadamard transforms.
Main Results and Discussion
- Sensitivity increased up to tenfold proportional to pulse count per transient (e.g., 20 pushes yield ~20 kHz extraction).
- Low-abundance isotopes and trace analytes in complex matrices become reliably detectable, expanding the lower end of the linear dynamic range while maintaining the upper end (Figure 6).
- EFP decoding removes non-coherent electrical and chemical noise, reducing baseline clutter and data file size (Figure 7).
- Spectral acquisition retains full mass range (10–1500 m/z) at high frequencies, avoiding the mass cut-off limitations of standard high-frequency extraction.
- Improved ion statistics from multiplexing enhance mass accuracy (MA ∼1/(R·√N)), particularly under rapid GCxGC acquisition (200 spectra/s) (Figure 8).
Practical Benefits and Applications
EFP enables higher throughput and sensitivity in environmental, forensic, and industrial QA/QC workflows by detecting lower concentration compounds without extending analysis time. The method integrates seamlessly with existing GC-HRT and GCxGC-HRT platforms, improving trace analysis, isotope ratio measurements, and high-speed separations.
Future Trends and Potential Applications
Further innovations may include adaptive encoding schemes tailored to sample complexity, integration with alternative ionization sources (e.g., APCI, MALDI), and real-time feedback loops for dynamic interval adjustment. EFP could be extended to other MR-TOF configurations and combined with machine-learning-based decoding to handle highly populated spectra.
Conclusion
Encoded Frequent Pushing significantly enhances the duty cycle and analytical performance of FFP high-resolution TOFMS by multiplexing ion extraction with unique timing and artifact-free decoding. The approach delivers up to tenfold sensitivity gains, extended dynamic range, full mass range operation, noise suppression, and improved mass accuracy, broadening the applicability of GC-HRT and GCxGC-HRT techniques.
References
- M. Guilhaus, D. Selby, V. Mlynski. Orthogonal Acceleration Time-of-Flight Mass Spectrometry. Mass Spectrometry Reviews, 2000, 19, 65–107.
- J. Franzen. High resolution method for using time-of-flight mass spectrometers with orthogonal ion injection. US Patent 6,861,645 (2003).
- D. Kenny, J. Wildgoose. An Orthogonal Acceleration Time-of-Flight Mass Spectrometer. GB Patent 2,445,679 (2007).
- F. Knorr. Fourier Transform Time-of-Flight Mass Spectrometer. US Patent 4,707,602 (1985).
- A. Brock, N. Rodriguez, R. Zare. Time-of-Flight Mass Spectrometer and Ion Analysis. US Patent 6,300,626 (1999).
- M. Belov, C. Fancher, P. Foley. Multiplexed Orthogonal Time-of-Flight Mass Spectrometer. US Patent 6,900,431 (2003).
- A. Verenchikov. Electrostatic Mass Spectrometer with Encoded Frequent Pulses. US Patent 8,853,623 (2011).
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