Halogenated hydrocarbons - Analysis of a CFC-standard for environmental analysis
Applications | 2011 | Agilent TechnologiesInstrumentation
Environmental monitoring of chlorofluorohydrocarbons (CFCs) is essential for tracking ozone-depleting substances and assessing air quality. Precise and rapid analysis of these compounds supports regulatory compliance and enables early detection of environmental hazards.
The primary goal of this study was to develop a gas chromatography (GC) method capable of separating and quantifying a standard mixture of ten CFCs within 20 minutes. The application note demonstrates method performance under defined chromatographic conditions for environmental analysis.
A GC-wide-bore technique was employed using an Agilent CP-SilicaPLOT column (0.53 mm × 30 m, 6 μm film thickness). The temperature program started at 50 °C (held 15 minutes) before ramping to 120 °C at 10 °C/min. Helium served as carrier gas at 40 kPa. A splitter injector delivered a 500 μL sample with a split ratio of 1:14 at 175 °C. Detection was carried out by a thermal conductivity detector (T = 200 °C). Sample concentration in air was 2 vol. %.
The optimized method achieved baseline separation of all ten CFCs in under 20 minutes. Peak identification followed this elution order: unretained gas, CFC-116, CFC-13, CFC-23, CFC-32, CFC-125, CFC-143A, CFC-22, CFC-134A, CFC-152A, and CFC-124. Chromatograms exhibited sharp peaks and consistent retention times, indicating robust column performance and reproducibility.
The described GC method offers several advantages:
This approach is readily applicable in environmental testing facilities, regulatory agencies, and industrial QA/QC labs.
Integration of mass spectrometric detection could further lower detection limits and improve compound identification. Automation of sample introduction and coupling with preconcentration systems may enhance sensitivity for trace-level monitoring. As environmental regulations evolve, adapting this method to emerging halogenated contaminants will expand its utility.
The Agilent CP-SilicaPLOT GC method provides a fast, reliable, and reproducible solution for separating and quantifying a standard mix of ten CFCs. Its straightforward operation and strong performance make it well suited for routine environmental analysis.
GC, GC columns, Consumables
IndustriesEnvironmental
ManufacturerAgilent Technologies
Summary
Importance of the Topic
Environmental monitoring of chlorofluorohydrocarbons (CFCs) is essential for tracking ozone-depleting substances and assessing air quality. Precise and rapid analysis of these compounds supports regulatory compliance and enables early detection of environmental hazards.
Objectives and Study Overview
The primary goal of this study was to develop a gas chromatography (GC) method capable of separating and quantifying a standard mixture of ten CFCs within 20 minutes. The application note demonstrates method performance under defined chromatographic conditions for environmental analysis.
Methodology and Instrumentation
A GC-wide-bore technique was employed using an Agilent CP-SilicaPLOT column (0.53 mm × 30 m, 6 μm film thickness). The temperature program started at 50 °C (held 15 minutes) before ramping to 120 °C at 10 °C/min. Helium served as carrier gas at 40 kPa. A splitter injector delivered a 500 μL sample with a split ratio of 1:14 at 175 °C. Detection was carried out by a thermal conductivity detector (T = 200 °C). Sample concentration in air was 2 vol. %.
Instrumentation Used
- Gas chromatograph with wide-bore inlet
- Agilent CP-SilicaPLOT fused silica column (Part no. CP8570)
- Helium carrier gas (40 kPa)
- Split injection system (split flow 53 mL/min)
- Thermal conductivity detector (200 °C)
Main Results and Discussion
The optimized method achieved baseline separation of all ten CFCs in under 20 minutes. Peak identification followed this elution order: unretained gas, CFC-116, CFC-13, CFC-23, CFC-32, CFC-125, CFC-143A, CFC-22, CFC-134A, CFC-152A, and CFC-124. Chromatograms exhibited sharp peaks and consistent retention times, indicating robust column performance and reproducibility.
Benefits and Practical Applications
The described GC method offers several advantages:
- Rapid analysis suited for high-throughput laboratories
- Clear separation of structurally similar halogenated hydrocarbons
- Reproducible retention and quantitation across runs
- Simple sample preparation with split injection
This approach is readily applicable in environmental testing facilities, regulatory agencies, and industrial QA/QC labs.
Future Trends and Opportunities
Integration of mass spectrometric detection could further lower detection limits and improve compound identification. Automation of sample introduction and coupling with preconcentration systems may enhance sensitivity for trace-level monitoring. As environmental regulations evolve, adapting this method to emerging halogenated contaminants will expand its utility.
Conclusion
The Agilent CP-SilicaPLOT GC method provides a fast, reliable, and reproducible solution for separating and quantifying a standard mix of ten CFCs. Its straightforward operation and strong performance make it well suited for routine environmental analysis.
Reference
- Agilent Technologies, Inc. Halogenated hydrocarbons: Analysis of a CFC-standard for environmental analysis. Application Note, October 2011.
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