Parts-per-Trillion Level Calibration of Semivolatiles Using LVI-PTV-GC/MSD
Applications | 2007 | Agilent TechnologiesInstrumentation
Accurate quantitation of semivolatile organic compounds at parts-per-trillion levels is critical for environmental monitoring and regulatory compliance.
Traditional injection and scan-only methods often lack the sensitivity and robustness needed to detect trace-level contaminants.
Employing large volume injection with programmable temperature vaporizing inlet (LVI-PTV) combined with SIM-mode GC/MSD overcomes these challenges and enhances detection capabilities.
This study demonstrates extension of the calibration range from 0.1 to 100 ppb and achievement of parts-per-trillion detection limits for over 100 semivolatile analytes in water.
Retention time locking and synchronized SIM/scan acquisition maintain reproducibility across numerous compound groups while allowing comprehensive data collection.
LVI-PTV operated in solvent vent mode with 25 µL injections at 50 µL per minute, initial inlet temperature 20 °C, solvent vent time 0.6 min at 100 mL per min, followed by rapid transfer at 350 °C.
GC oven program: 40 °C hold 2.5 min, ramp to 110 °C at 50 °C per min, then to 320 °C at 10 °C per min over a total runtime of 26 min.
MSD in SIM/scan mode with AutoSIM for ion selection, source temperature 300 °C, transfer line 280 °C, mass range 45–450 amu.
Approximately ten data points per peak enabled both sensitive quantitation (10–50× improvement in signal-to-noise) and full-scan identification of unknowns.
Calibration across 0.1 to 100 ppb showed excellent linearity with average relative standard deviations of response factors around 12 percent.
Most analytes achieved signal-to-noise ratios above three at the 100 ppt level; chlorpyrifos and phenamiphos were near the detection limit with ratios of 2.7 and 3.2, respectively.
System inertness confirmed by less than 2 percent breakdown of DDT to DDD and DDE and surrogate standard repeatability within 2–4 percent RSD.
Large volume injection with PTV-SIM enhances sensitivity while reducing sample preparation by up to two orders of magnitude.
Retention time locking simplifies method maintenance and ensures consistent SIM group switching times.
The workflow is well suited for drinking water quality assurance, environmental surveillance, and pesticide residue testing.
LVI-PTV coupled with SIM-mode GC/MSD enables reliable parts-per-trillion quantitation of semivolatiles with robust linearity, minimal analyte degradation, and streamlined sample preparation.
Retention time locking further enhances reproducibility and ease of method transfer for environmental analytical laboratories.
GC/MSD, GC/SQ
IndustriesEnvironmental
ManufacturerAgilent Technologies
Summary
Significance of the Topic
Accurate quantitation of semivolatile organic compounds at parts-per-trillion levels is critical for environmental monitoring and regulatory compliance.
Traditional injection and scan-only methods often lack the sensitivity and robustness needed to detect trace-level contaminants.
Employing large volume injection with programmable temperature vaporizing inlet (LVI-PTV) combined with SIM-mode GC/MSD overcomes these challenges and enhances detection capabilities.
Objectives and Overview
This study demonstrates extension of the calibration range from 0.1 to 100 ppb and achievement of parts-per-trillion detection limits for over 100 semivolatile analytes in water.
Retention time locking and synchronized SIM/scan acquisition maintain reproducibility across numerous compound groups while allowing comprehensive data collection.
Methodology and Used Instrumentation
LVI-PTV operated in solvent vent mode with 25 µL injections at 50 µL per minute, initial inlet temperature 20 °C, solvent vent time 0.6 min at 100 mL per min, followed by rapid transfer at 350 °C.
GC oven program: 40 °C hold 2.5 min, ramp to 110 °C at 50 °C per min, then to 320 °C at 10 °C per min over a total runtime of 26 min.
MSD in SIM/scan mode with AutoSIM for ion selection, source temperature 300 °C, transfer line 280 °C, mass range 45–450 amu.
Used Instrumentation
- Gas chromatograph Agilent 7890A or 6890N with EPC PTV inlet
- Mass spectrometer Agilent 5975C Trace Ion Detector
- HP-5MSi column 30 m × 0.25 mm × 0.25 µm
- Autosampler with 50 µL syringe
Main Results and Discussion
Approximately ten data points per peak enabled both sensitive quantitation (10–50× improvement in signal-to-noise) and full-scan identification of unknowns.
Calibration across 0.1 to 100 ppb showed excellent linearity with average relative standard deviations of response factors around 12 percent.
Most analytes achieved signal-to-noise ratios above three at the 100 ppt level; chlorpyrifos and phenamiphos were near the detection limit with ratios of 2.7 and 3.2, respectively.
System inertness confirmed by less than 2 percent breakdown of DDT to DDD and DDE and surrogate standard repeatability within 2–4 percent RSD.
Benefits and Practical Applications
Large volume injection with PTV-SIM enhances sensitivity while reducing sample preparation by up to two orders of magnitude.
Retention time locking simplifies method maintenance and ensures consistent SIM group switching times.
The workflow is well suited for drinking water quality assurance, environmental surveillance, and pesticide residue testing.
Future Trends and Possibilities
- Adoption of faster cooling ovens and rear-mounted mass detectors for increased throughput
- Automation of SIM table generation and advanced ion selection algorithms
- Extension to non-targeted screening of emerging contaminants
- Integration with high-resolution mass spectrometry for combined sensitivity and mass accuracy
Conclusion
LVI-PTV coupled with SIM-mode GC/MSD enables reliable parts-per-trillion quantitation of semivolatiles with robust linearity, minimal analyte degradation, and streamlined sample preparation.
Retention time locking further enhances reproducibility and ease of method transfer for environmental analytical laboratories.
Reference
- U.S. EPA Method 525.2
- M. Szelewski Drinking Water Semivolatile Analysis Using the 6890N/5975B Inert GC/MSD Agilent Technologies publication 5989-5421EN
- K. Weiner N. Mata and P. Wylie Retention Time Locking with the G1701BA MSD Productivity ChemStation Agilent Technologies publication 5968-3433E
- M. Szelewski B. Wilson and P. Perkins Improvements in the Agilent 6890/5973 GC/MSD System for Use with U.S. EPA Method 8270 Agilent Technologies publication 5988-3072EN
- H. Prest and D. Peterson New Approaches to the Development of GC/MS Selected Ion Monitoring Acquisition and Quantitation Methods Agilent Technologies publication 5988-4188
- M. Szelewski Synchronous SIM/Scan Low-Level PAH Analysis Using the Agilent Technologies 6890/5975 Inert GC/MSD Agilent Technologies publication 5989-4184EN
Content was automatically generated from an orignal PDF document using AI and may contain inaccuracies.
Similar PDF
Femtogram GC/MSD Detection Limits for Environmental Semivolatiles Using a Triple-Axis Detector
2008|Agilent Technologies|Applications
Femtogram GC/MSD Detection Limits for Environmental Semivolatiles Using a Triple-Axis Detector Application Environmental Author Mike Szelewski Agilent Technologies, Inc. 2850 Centerville Road Wilmington, DE 19808 USA Abstract The analysis of semivolatiles at very low levels presents challenges due to analyte…
Key words
sim, simsolv, solvwashes, washesscan, scanptv, ptvmsd, msdcryo, cryotemp, temppurge, purgeoven, ovensemivolatiles, semivolatilespostinj, postinjpreinj, preinjpentachlorophenol, pentachlorophenolautosim
Reducing Analysis Time Using GC/MSD and Deconvolution Reporting Software
2007|Agilent Technologies|Applications
Reducing Analysis Time Using GC/MSD and Deconvolution Reporting Software Application Food and Flavors Authors Mike Grady, Steve Morrison, and Bob Deets Campbell Soup Company Campbell Place Camden, NJ 08103 USA Mike Szelewski Agilent Technologies, Inc. 2850 Centerville Road Wilmington, DE…
Key words
msd, msddrs, drswashes, washessolv, solvcampbell, campbellpermethrin, permethrindeconvolution, deconvolutionfewest, fewestcryo, cryolocked, lockednegatives, negativespositives, positivespostinj, postinjpreinj, preinjvent
Semivolatiles Retention Time Locked (RTL) Deconvolution Databases for Agilent GC/MSD Systems
2008|Agilent Technologies|Applications
Semivolatiles Retention Time Locked (RTL) Deconvolution Databases for Agilent GC/MSD Systems Application Environmental Author Mike Szelewski Agilent Technologies, Inc. 2850 Centerville Road Wilmington, DE 19808 USA Abstract The G1677AA Semivolatiles Retention Time Locked database/library can provide rapid confirmation of environmental…
Key words
entry, entrydrs, drsmsd, msdcas, casamdis, amdisphthalate, phthalatebenzo, benzoconfigurator, configuratorlocked, lockedretention, retentionfluoranthene, fluoranthenename, nametime, timedbl, dblcompound
Drinking Water Semivolatiles Analysis using the 6890N/5975B inert GC/MSD
2006|Agilent Technologies|Applications
Drinking Water Semivolatiles Analysis using the 6890N/5975B inert GC/MSD Application Author Mike Szelewski Agilent Technologies, Inc. 2850 Centerville Road Wilmington, DE 19808 USA Abstract The analysis of semivolatiles in drinking water presents challenges due to the required detection limits, desired…
Key words
msd, msdrtl, rtlsemivolatiles, semivolatilessim, siminlet, inlettuning, tuningdftpp, dftppdrinking, drinkingrrf, rrfscan, scanfull, fullrsd, rsdtemperature, temperatureptv, ptvrange
