Analysis of US EPA Method 8270D Semivolatiles Using a 30 m x 0.25 mm I.D., 0.50 μm SLB-5ms
Applications | 2006 | MerckInstrumentation
Semivolatile organic compounds represent a diverse class of environmental contaminants regulated under US EPA Method 8270D. Reliable detection in soil, groundwater and solid waste is essential for risk assessment, regulatory compliance and remediation monitoring.
This application report evaluates the performance of a 30 m × 0.25 mm I.D., 0.50 µm SLB-5ms column paired with an Agilent 6890 GC/5973 MSD for semivolatiles analysis. The main goals were to extend calibration range, improve sample capacity and maintain chromatographic resolution within acceptable analysis times.
The study followed US EPA 8270D guidelines using a 72-component semivolatile standard with surrogate and internal standards.
The 0.50 µm film thickness increased sample capacity without compromising chromatographic resolution. A full separation of target analytes was achieved in under 35 minutes with consistent retention times and sharp peak shapes. Calibration curves remained linear over an extended concentration range, reducing the need for sample dilution in higher-level analyses. Sensitivity and reproducibility met or exceeded method requirements.
Advances in column technology and faster oven heating rates may further decrease analysis times. Integration with high-resolution mass spectrometers and automated data processing will enhance identification confidence and throughput. Miniaturized GC systems and novel stationary phases could offer field-deployable solutions.
Employing a 0.50 µm SLB-5ms column under EPA 8270D conditions delivers an optimized balance of sample capacity, resolution and run time. This approach streamlines semivolatile analysis, extends calibration limits and supports reliable environmental testing.
GC/MSD, GC columns, Consumables
IndustriesEnvironmental
ManufacturerMerck
Summary
Significance of the Topic
Semivolatile organic compounds represent a diverse class of environmental contaminants regulated under US EPA Method 8270D. Reliable detection in soil, groundwater and solid waste is essential for risk assessment, regulatory compliance and remediation monitoring.
Objectives and Study Overview
This application report evaluates the performance of a 30 m × 0.25 mm I.D., 0.50 µm SLB-5ms column paired with an Agilent 6890 GC/5973 MSD for semivolatiles analysis. The main goals were to extend calibration range, improve sample capacity and maintain chromatographic resolution within acceptable analysis times.
Methodology and Instrumentation
The study followed US EPA 8270D guidelines using a 72-component semivolatile standard with surrogate and internal standards.
- Column: SLB-5ms, 30 m × 0.25 mm I.D., 0.50 µm film
- Oven program: 40 °C (1 min), 12 °C/min to 250 °C, 25 °C/min to 340 °C (4.5 min)
- Injection: 1.0 µL splitless, inlet at 250 °C, 0.50 min hold
- Carrier gas: helium at 1.5 mL/min constant flow
- MSD conditions: transfer line 340 °C, scan range m/z 40–450
- On-column load: 50 ng analyte, 40 ng internal standards
Main Results and Discussion
The 0.50 µm film thickness increased sample capacity without compromising chromatographic resolution. A full separation of target analytes was achieved in under 35 minutes with consistent retention times and sharp peak shapes. Calibration curves remained linear over an extended concentration range, reducing the need for sample dilution in higher-level analyses. Sensitivity and reproducibility met or exceeded method requirements.
Benefits and Practical Applications of the Method
- Extended dynamic range allows direct analysis of higher-concentration samples.
- Improved robustness reduces column overload and peak distortion.
- Maintained throughput with run times compatible with routine laboratory schedules.
- Applicable to environmental monitoring, waste characterization and regulatory compliance testing.
Future Trends and Possibilities
Advances in column technology and faster oven heating rates may further decrease analysis times. Integration with high-resolution mass spectrometers and automated data processing will enhance identification confidence and throughput. Miniaturized GC systems and novel stationary phases could offer field-deployable solutions.
Conclusion
Employing a 0.50 µm SLB-5ms column under EPA 8270D conditions delivers an optimized balance of sample capacity, resolution and run time. This approach streamlines semivolatile analysis, extends calibration limits and supports reliable environmental testing.
References
- US EPA Method 8270D: Semivolatiles by GC/MS
- Application Report 401, Sigma-Aldrich Co., Katherine Stenerson, 2006
- Agilent 6890 GC/5973 MSD System Documentation
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