Hydrocarbons, C6 – C7, aromatic hydrocarbons, C6 – C8 - Analysis of impurities in cyclohexane
Applications | 2011 | Agilent TechnologiesInstrumentation
Cyclohexane serves as a ubiquitous solvent and chemical intermediate in petrochemical and pharmaceutical industries. Even trace-level hydrocarbon impurities can affect product performance, safety, and regulatory compliance. A rapid and reliable analytical approach is essential for quality control and process monitoring.
This application note presents a capillary gas chromatography method with flame ionization detection (GC-FID) for quantifying C6–C8 aliphatic and aromatic impurities in cyclohexane. The primary goals are to achieve detection limits in the low ppm range, maintain high reproducibility, and complete analyses within 10–15 minutes using a single column type.
Samples of cyclohexane spiked with impurities (1–200 ppm) were injected (2 µL) in split mode. The oven program began at 70 °C (2 min), ramped at 20 °C/min to 200 °C (hold 5 min). Hydrogen (1.5 bar) served as carrier gas. Detection was performed by FID at 250 °C.
The method achieved baseline separation of eleven analytes, including benzene, toluene, xylenes, heptane, methylcyclohexane, and methylcyclopentane. Typical analysis times were 10–15 minutes. Reproducibility was within 3% RSD for concentrations between 5 and 500 ppm, with reliable detection down to 1–5 ppm. The thick-film column overcame loading limitations common to narrow-bore columns, ensuring accurate trace-level quantification.
Implementing this GC-FID method allows laboratories to consolidate hydrocarbon impurity analyses onto a single column type, reducing inventory and method development time. The rapid run times and low detection limits support quality assurance, environmental monitoring, and regulatory compliance in industrial settings.
Emerging stationary phase technologies and microfabricated columns may further decrease analysis time and improve sensitivity. Integration with mass spectrometric detectors could enable broader screening of non-hydrocarbon contaminants and complex sample matrices.
The described GC-FID approach offers a robust, sensitive, and efficient solution for trace-level impurity analysis in cyclohexane. Its reproducibility, speed, and broad applicability make it well suited for routine petrochemical quality control and research applications.
GC, GC columns, Consumables
IndustriesEnergy & Chemicals
ManufacturerAgilent Technologies
Summary
Significance of the Topic
Cyclohexane serves as a ubiquitous solvent and chemical intermediate in petrochemical and pharmaceutical industries. Even trace-level hydrocarbon impurities can affect product performance, safety, and regulatory compliance. A rapid and reliable analytical approach is essential for quality control and process monitoring.
Objectives and Study Overview
This application note presents a capillary gas chromatography method with flame ionization detection (GC-FID) for quantifying C6–C8 aliphatic and aromatic impurities in cyclohexane. The primary goals are to achieve detection limits in the low ppm range, maintain high reproducibility, and complete analyses within 10–15 minutes using a single column type.
Methodology
Samples of cyclohexane spiked with impurities (1–200 ppm) were injected (2 µL) in split mode. The oven program began at 70 °C (2 min), ramped at 20 °C/min to 200 °C (hold 5 min). Hydrogen (1.5 bar) served as carrier gas. Detection was performed by FID at 250 °C.
Used Instrumentation
- Agilent GC system equipped with a 0.15 mm × 25 m CP-Sil 5 CB fused-silica capillary column (1.2 μm film)
- Split injector operated at 250 °C
- Flame ionization detector at 250 °C
- Hydrogen carrier gas at 150 kPa (21 psi)
Results and Discussion
The method achieved baseline separation of eleven analytes, including benzene, toluene, xylenes, heptane, methylcyclohexane, and methylcyclopentane. Typical analysis times were 10–15 minutes. Reproducibility was within 3% RSD for concentrations between 5 and 500 ppm, with reliable detection down to 1–5 ppm. The thick-film column overcame loading limitations common to narrow-bore columns, ensuring accurate trace-level quantification.
Practical Benefits and Applications
Implementing this GC-FID method allows laboratories to consolidate hydrocarbon impurity analyses onto a single column type, reducing inventory and method development time. The rapid run times and low detection limits support quality assurance, environmental monitoring, and regulatory compliance in industrial settings.
Future Trends and Potential Applications
Emerging stationary phase technologies and microfabricated columns may further decrease analysis time and improve sensitivity. Integration with mass spectrometric detectors could enable broader screening of non-hydrocarbon contaminants and complex sample matrices.
Conclusion
The described GC-FID approach offers a robust, sensitive, and efficient solution for trace-level impurity analysis in cyclohexane. Its reproducibility, speed, and broad applicability make it well suited for routine petrochemical quality control and research applications.
References
- Agilent Technologies, Inc. Analysis of impurities in cyclohexane. Application Note A01393. October 31, 2011.
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