Fast USEPA 8270 Semivolatiles Analysis Using the 6890/5973 inert GC/MSD with Performance Electronics
Technical notes | 2004 | Agilent TechnologiesInstrumentation
Gas chromatography coupled with mass spectrometry (GC/MS) remains a cornerstone technique in analytical chemistry for qualitative and quantitative analysis of organic compounds. Advances in instrument electronics are critical to accommodate faster chromatography while preserving spectral fidelity, sensitivity, and ion-ratio accuracy.
This study examines the performance improvements of the Agilent 5973 Inert MSD’s new electronics, capable of scan speeds up to 10000 amu/s. It evaluates optimal scan and SIM acquisition parameters to ensure reliable compound detection and quantitation in both high-throughput quantitative assays and qualitative screening applications.
The method development considered column phase, film thickness, gas flow, and oven programs to achieve narrow, consistent peak widths. GC conditions included an HP-5ms column (30 m × 0.25 mm i.d., 0.25 µm film), pulsed splitless injection (275 °C), and an oven ramp from 50 °C to 325 °C. The Agilent 5973 Inert MSD operated with new Performance Electronics in scan mode (m/z 150–510) and SIM mode (up to 50 groups, 30 ions per group, 10 ms minimum dwell) under retention-time locking. AutoSIM software automated SIM group creation and dwell time settings for 10 scans per peak.
In quantitative mode, 8–10 scans per peak are required to achieve ±1% ion-ratio accuracy. For qualitative screening, 4–5 scans per peak suffice when using deconvolution software (DRS with AMDIS). Performance plots correlate chromatographic peak width and mass range with scan sampling (2^n) to guide parameter selection. Experimental analysis of 20 PCBs (biphenyl to decachlorobiphenyl) in an 8.7 min run yielded average base peak widths of ~3.9 s. Biphenyl (2.7 s width) produced ~6 scans at 2^3 sampling, ~10 at 2^2, ~17 at 2^1, ~30 at 2^0, and ~50 in Fast mode. Faster scans maintained spectral quality with minimal signal loss compared to legacy electronics. In SIM, dwell times shorten with sharper peaks and larger ion groups, necessitating group size adjustment to maintain 10 scans per peak.
Continued miniaturization and faster electronics will push GC/MS to sub-minute separations. Integration of AI-driven method optimization and real-time data evaluation may further streamline qualitative and quantitative workflows. Emerging detector technologies and software enhancements will expand applications in metabolomics, forensics, and complex mixture analysis.
Optimizing GC/MS scan and SIM acquisition requires balancing mass range, scan speed, and chromatographic peak width to obtain the necessary number of scans per peak. The Agilent 5973 Inert MSD with Performance Electronics achieves high scan rates with maintained spectral quality. Employ narrow mass windows, appropriate sampling (2^n), and leverage AutoSIM and retention-time locking for reliable, high-throughput analyses.
GC/MSD, GC/SQ
IndustriesManufacturerAgilent Technologies
Summary
Importance of Topic
Gas chromatography coupled with mass spectrometry (GC/MS) remains a cornerstone technique in analytical chemistry for qualitative and quantitative analysis of organic compounds. Advances in instrument electronics are critical to accommodate faster chromatography while preserving spectral fidelity, sensitivity, and ion-ratio accuracy.
Objectives and Study Overview
This study examines the performance improvements of the Agilent 5973 Inert MSD’s new electronics, capable of scan speeds up to 10000 amu/s. It evaluates optimal scan and SIM acquisition parameters to ensure reliable compound detection and quantitation in both high-throughput quantitative assays and qualitative screening applications.
Methodology and Instrumentation
The method development considered column phase, film thickness, gas flow, and oven programs to achieve narrow, consistent peak widths. GC conditions included an HP-5ms column (30 m × 0.25 mm i.d., 0.25 µm film), pulsed splitless injection (275 °C), and an oven ramp from 50 °C to 325 °C. The Agilent 5973 Inert MSD operated with new Performance Electronics in scan mode (m/z 150–510) and SIM mode (up to 50 groups, 30 ions per group, 10 ms minimum dwell) under retention-time locking. AutoSIM software automated SIM group creation and dwell time settings for 10 scans per peak.
- GC Column HP-5ms, 30 m × 0.25 mm i.d., 0.25 µm film
- Injection Pulsed splitless, 1 µL, 275 °C
- Oven Program 50 °C (1 min), 45 °C/min to 325 °C (1.6 min)
- MSD Agilent 5973 Inert MSD with Performance Electronics
- Scan Range 150–510 amu, electronic scan speed up to 10000 amu/s
- SIM up to 30 ions/group, 50 groups, 10 ms minimum dwell
Key Results and Discussion
In quantitative mode, 8–10 scans per peak are required to achieve ±1% ion-ratio accuracy. For qualitative screening, 4–5 scans per peak suffice when using deconvolution software (DRS with AMDIS). Performance plots correlate chromatographic peak width and mass range with scan sampling (2^n) to guide parameter selection. Experimental analysis of 20 PCBs (biphenyl to decachlorobiphenyl) in an 8.7 min run yielded average base peak widths of ~3.9 s. Biphenyl (2.7 s width) produced ~6 scans at 2^3 sampling, ~10 at 2^2, ~17 at 2^1, ~30 at 2^0, and ~50 in Fast mode. Faster scans maintained spectral quality with minimal signal loss compared to legacy electronics. In SIM, dwell times shorten with sharper peaks and larger ion groups, necessitating group size adjustment to maintain 10 scans per peak.
Benefits and Practical Applications
- Enhanced throughput via rapid GC/MS analysis without compromised sensitivity
- Consistent ion-ratio accuracy and spectral fidelity up to 10000 amu/s
- Automated SIM method setup and retention-time locking reduce maintenance
- Applicable to environmental monitoring, pesticide screening, QA/QC, and industrial analytics
Future Trends and Potential Applications
Continued miniaturization and faster electronics will push GC/MS to sub-minute separations. Integration of AI-driven method optimization and real-time data evaluation may further streamline qualitative and quantitative workflows. Emerging detector technologies and software enhancements will expand applications in metabolomics, forensics, and complex mixture analysis.
Conclusion
Optimizing GC/MS scan and SIM acquisition requires balancing mass range, scan speed, and chromatographic peak width to obtain the necessary number of scans per peak. The Agilent 5973 Inert MSD with Performance Electronics achieves high scan rates with maintained spectral quality. Employ narrow mass windows, appropriate sampling (2^n), and leverage AutoSIM and retention-time locking for reliable, high-throughput analyses.
Reference
- 1. Matthews DE and Hayes JM, Systematic Errors in Gas Chromatography-Mass Spectrometry Isotope Ratio Measurements, Analytical Chemistry, 48, 1375–1382 (1976).
- 2. Wylie PL et al, Comprehensive Pesticide Screening by GC/MSD using Deconvolution Reporting Software, Agilent Technologies, publication 5989-1157EN.
- 3. Prest H and Peterson DW, New approaches to the development of GC-MS selected ion monitoring acquisition and quantitation methods, Agilent Technologies, publication 5988-4188EN.
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