Using Alternative Carrier Gas for US EPA 524.3
Applications | 2013 | Teledyne LABSInstrumentation
Ensuring safe drinking water requires reliable detection of volatile organic compounds (VOCs) at trace levels. USEPA Method 524.3 is a key protocol for measuring purgeable organics by capillary GC/MS. Due to increasing helium shortages and cost, investigating renewable carrier and purge gases is critical for sustainable, cost-effective laboratory operations.
This study examines the feasibility of replacing helium with hydrogen as carrier gas and nitrogen as purge gas for EPA Method 524.3. Key goals include evaluating calibration linearity, precision, accuracy, and mass spectrometer tuning under alternative gases using the Atomx multimatrix autosampler coupled to a TRACE 1310 GC/MS.
Calibration standards (0.5 to 50 ppb) were prepared in reagent water with ascorbic and maleic acids and analyzed according to Method 524.3. A weighted quadratic regression was applied, targeting r² ≥ 0.995. Precision and accuracy were assessed on eight replicates at the 10 ppb midpoint. 4-Bromofluorobenzene (BFB) tune checks ensured MS performance under hydrogen.
Calibration curves for over 60 VOCs met the linearity requirement (r² between 0.996 and 0.999). Precision (%RSD) at 10 ppb was generally below 15%, and average accuracy deviations fell within ±15% for most analytes. The lowest point (0.5 ppb) remained within ±50% tolerance. BFB ion-ratio criteria were satisfied, confirming robust MS tuning with hydrogen carrier gas. Overall performance was comparable to helium-based runs.
Further validation for a broader range of analytes and matrices will strengthen regulatory acceptance. Integration of on-site hydrogen/nitrogen generators can improve lab sustainability. Method updates and guidance are anticipated to include alternative gases in official protocols.
The combination of hydrogen carrier gas and nitrogen purge gas with the Atomx/TRACE 1310 GC/MS meets all performance requirements of USEPA Method 524.3. This approach offers a reliable, cost-effective, and environmentally friendly alternative to helium.
GC/MSD, Purge and Trap, GC/SQ
IndustriesEnvironmental
ManufacturerThermo Fisher Scientific, Teledyne LABS
Summary
Importance of the Topic
Ensuring safe drinking water requires reliable detection of volatile organic compounds (VOCs) at trace levels. USEPA Method 524.3 is a key protocol for measuring purgeable organics by capillary GC/MS. Due to increasing helium shortages and cost, investigating renewable carrier and purge gases is critical for sustainable, cost-effective laboratory operations.
Objectives and Study Overview
This study examines the feasibility of replacing helium with hydrogen as carrier gas and nitrogen as purge gas for EPA Method 524.3. Key goals include evaluating calibration linearity, precision, accuracy, and mass spectrometer tuning under alternative gases using the Atomx multimatrix autosampler coupled to a TRACE 1310 GC/MS.
Instrumentation Used
- Teledyne Tekmar Atomx Multimatrix Autosampler (purge-and-trap concentrator with 80-position vial autosampler)
- Thermo Scientific TRACE 1310 gas chromatograph with ISQ mass spectrometer
- Rtx-VMS capillary column (20 m × 0.18 mm × 1 µm)
- Hydrogen carrier gas at 0.8 mL/min, 5 psi split; nitrogen purge gas
Methodology
Calibration standards (0.5 to 50 ppb) were prepared in reagent water with ascorbic and maleic acids and analyzed according to Method 524.3. A weighted quadratic regression was applied, targeting r² ≥ 0.995. Precision and accuracy were assessed on eight replicates at the 10 ppb midpoint. 4-Bromofluorobenzene (BFB) tune checks ensured MS performance under hydrogen.
Main Results and Discussion
Calibration curves for over 60 VOCs met the linearity requirement (r² between 0.996 and 0.999). Precision (%RSD) at 10 ppb was generally below 15%, and average accuracy deviations fell within ±15% for most analytes. The lowest point (0.5 ppb) remained within ±50% tolerance. BFB ion-ratio criteria were satisfied, confirming robust MS tuning with hydrogen carrier gas. Overall performance was comparable to helium-based runs.
Benefits and Practical Applications
- Reduced operating costs through in-house hydrogen and nitrogen generation
- Lower environmental impact by conserving nonrenewable helium
- Enhanced sample throughput via automated Atomx prep and self-loading
- Straightforward retrofit of existing GC/MS systems
Future Trends and Applications
Further validation for a broader range of analytes and matrices will strengthen regulatory acceptance. Integration of on-site hydrogen/nitrogen generators can improve lab sustainability. Method updates and guidance are anticipated to include alternative gases in official protocols.
Conclusion
The combination of hydrogen carrier gas and nitrogen purge gas with the Atomx/TRACE 1310 GC/MS meets all performance requirements of USEPA Method 524.3. This approach offers a reliable, cost-effective, and environmentally friendly alternative to helium.
References
- USEPA Method 524.3, Measurement of Purgeable Organic Compounds in Water by Capillary Column GC/MS, U.S. EPA Office of Ground Water and Drinking Water, 2009.
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