Analysis of Thiophene in Benzene
Applications | 2022 | ShimadzuInstrumentation
Monitoring trace levels of sulfur compounds in petrochemical feedstocks is critical for ensuring product quality, preventing catalyst poisoning, and complying with environmental regulations. Thiophene, a common sulfur heterocycle, can adversely affect downstream processing and lead to harmful emissions if not effectively controlled. Precise quantification of thiophene in benzene at sub-ppm levels therefore supports both industrial efficiency and environmental stewardship.
This application note demonstrates a streamlined gas chromatography method equipped with a flame photometric detector selective for sulfur to quantify thiophene in benzene. The primary goal is to achieve reliable detection at 0.1 ppm with short analysis time, minimal sample preparation, and robust automation to meet high-throughput laboratory demands.
The analysis employs a Nexis GC-2030 system paired with an AOC-20i autosampler and LabSolutions software. Key parameters include:
The method achieved baseline resolution of thiophene from benzene within a total run time of 7 minutes. Calibration demonstrated linear response across the 0.05–1 ppm range, with a limit of detection below 0.05 ppm. Repeatability over six injections yielded relative standard deviation under 3 %. The selective sulfur response reduced matrix interferences and ensured accurate quantification in complex samples.
Key advantages of this approach include rapid throughput, high selectivity for sulfur species, and compatibility with automated sampling. Laboratories in petrochemical QC, environmental monitoring, and catalyst evaluation can adopt this protocol to maintain tight control over sulfur impurities, optimize refining processes, and certify product compliance.
Advances in detector technology and high-efficiency columns may further shorten analysis time and lower detection limits. Integration with on-line sampling interfaces and remote monitoring systems is expected to streamline real-time sulfur surveillance in continuous processes. Coupling with mass spectrometric detectors could expand the scope to other trace contaminants.
This work presents a concise, sensitive GC-FPD method for detecting thiophene at 0.1 ppm in benzene, combining selectivity, speed, and reproducibility. The protocol supports stringent quality control and environmental protection goals in industrial laboratories.
Application News G291, Shimadzu Corporation, First Edition: September 2022
GC, GC columns, Consumables
IndustriesEnergy & Chemicals
ManufacturerShimadzu
Summary
Significance of the Topic
Monitoring trace levels of sulfur compounds in petrochemical feedstocks is critical for ensuring product quality, preventing catalyst poisoning, and complying with environmental regulations. Thiophene, a common sulfur heterocycle, can adversely affect downstream processing and lead to harmful emissions if not effectively controlled. Precise quantification of thiophene in benzene at sub-ppm levels therefore supports both industrial efficiency and environmental stewardship.
Study Objectives and Overview
This application note demonstrates a streamlined gas chromatography method equipped with a flame photometric detector selective for sulfur to quantify thiophene in benzene. The primary goal is to achieve reliable detection at 0.1 ppm with short analysis time, minimal sample preparation, and robust automation to meet high-throughput laboratory demands.
Methodology and Instrumentation
The analysis employs a Nexis GC-2030 system paired with an AOC-20i autosampler and LabSolutions software. Key parameters include:
- Injection: 1 µL direct liquid injection via a WBI unit at 200 °C
- Column: SH-PolarWax, 30 m × 0.53 mm I.D., 2 µm film
- Oven Program: isothermal at 75 °C for 7 minutes
- Carrier Gas: helium at constant flow of 10 mL/min; purge at 3 mL/min
- Detector: FPD-2030(S) set at 230 °C with H₂ (40 mL/min) and air (60 mL/min)
Main Results and Discussion
The method achieved baseline resolution of thiophene from benzene within a total run time of 7 minutes. Calibration demonstrated linear response across the 0.05–1 ppm range, with a limit of detection below 0.05 ppm. Repeatability over six injections yielded relative standard deviation under 3 %. The selective sulfur response reduced matrix interferences and ensured accurate quantification in complex samples.
Benefits and Practical Applications
Key advantages of this approach include rapid throughput, high selectivity for sulfur species, and compatibility with automated sampling. Laboratories in petrochemical QC, environmental monitoring, and catalyst evaluation can adopt this protocol to maintain tight control over sulfur impurities, optimize refining processes, and certify product compliance.
Future Trends and Potential Uses
Advances in detector technology and high-efficiency columns may further shorten analysis time and lower detection limits. Integration with on-line sampling interfaces and remote monitoring systems is expected to streamline real-time sulfur surveillance in continuous processes. Coupling with mass spectrometric detectors could expand the scope to other trace contaminants.
Conclusion
This work presents a concise, sensitive GC-FPD method for detecting thiophene at 0.1 ppm in benzene, combining selectivity, speed, and reproducibility. The protocol supports stringent quality control and environmental protection goals in industrial laboratories.
References
Application News G291, Shimadzu Corporation, First Edition: September 2022
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